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Article

Monitoring the Effect of Metal Ions on the Mobility of Artemia salina Nauplii

by
Varvara Kokkali
1,
Ioannis Katramados
2 and
Jeffrey D. Newman
1,*
1
Cranfield Health, Vincent Building, Cranfield University, Cranfield, Bedfordshire, MK43 0AL, UK
2
School of Engineering, Whittle building, Cranfield University, Cranfield, Bedfordshire, MK43 0AL, UK
*
Author to whom correspondence should be addressed.
Biosensors 2011, 1(2), 36-45; https://doi.org/10.3390/bios1020036
Submission received: 9 February 2011 / Revised: 8 March 2011 / Accepted: 22 March 2011 / Published: 28 March 2011
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Abstract

:
This study aims to measure the effect of toxic aqueous solutions of metals on the mobility of Artemia salina nauplii by using digital image processing. The instrument consists of a camera with a macro lens, a dark chamber, a light source and a laptop computer. Four nauplii were inserted into a macro cuvette, which contained copper, cadmium, iron and zinc ions at various concentrations. The nauplii were then filmed inside the dark chamber for two minutes and the video sequence was processed by a motion tracking algorithm that estimated their mobility. The results obtained by this system were compared to the mortality assay of the Artemia salina nauplii. Despite the small number of tested organisms, this system demonstrates great sensitivity in quantifying the mobility of the nauplii, which leads to significantly lower EC50 values than those of the mortality assay. Furthermore, concentrations of parts per trillion of toxic compounds could be detected for some of the metals. The main novelty of this instrument relies in the sub-pixel accuracy of the tracking algorithm that enables robust measurement of the deterioration of the mobility of Artemia salina even at very low concentrations of toxic metals.

Graphical Abstract

1. Introduction

The ongoing interest in assessing the environmental effect of toxic waste materials has led to an increasing number of bioassays and screening devices. Such techniques are often based on measuring the effect of toxic substances on the behaviour and life cycle of microorganisms, invertebrates and algae. Different biological properties that have been utilized for toxicity screening include the luminescence of Vibrio fischeri, respiratory rate of aerobic bacteria, enzyme activity of Daphnia magna, fluorescence of Chlorella vulgari (algae) and the lethality to crustaceans (such as Artemia salina). In addition, several studies have specifically focused on the impact of metals to the biota, by analysing their toxic effect to crustaceans. Giarratano et al. [1] and Lorenzon et al. [2] have investigated the effect of heavy metals to Exosphaeroma gigas and Palaemon elegans respectively. Furthermore, MacRae and Pandey [3] have researched the relation between water toxicity and hatching success of Artemia species. Similarly, Gajbhiye and Hirota [4] have proved that the lethality of these species is dependent on the concentration of heavy metals in water.
Artemia species, or brine shrimps, have also been used in many scientific experiments for acute toxicity testing of toxic materials including pesticides (Barahona & Sánchez-Fortún [5]), leachates (Svensson et al. [6]), dental materials (Pelka et al. [7]), fungal toxins (Harwig & Scott, [8]) and antifouling biocides (Koutsaftis and Aoyama [9]). Although Artemia species are not considered as sensitive as other screening instruments or organisms (Nunes et al. [10]), they have some important advantages including constant commercial availability all year round, cost efficiency, ease of culture, short life-cycle, no feeding required during the assay and great offspring production (Vanhaecke et al. [11]).
These advantages have led to a wide range of Artemia-based bioassays. The determination of the LC50 of the nauplii (instar II-III stage) (Vanhaecke and Persoone [12]), the hatchability of the cysts (MacRae and Pandey [3]), the different age specimens (Barahona and Sánchez-Fortún, [5]) and the disruptions on an enzyme property (Varó et al. [13,14]) are only some of the Artemia end-points that have already been examined as evidence of toxicity. Specifically, Vanhaecke and Persoone [12] have demonstrated a shrimp-based bioassay, known as the ARC-test (Artemia Reference Centre), with highly reproducible and accurate results. Additionally, Vanhaecke et al. [15] proved that the most sensitive age for the majority of the tested compounds were the 48-h old nauplii at the stage of instar II-III. The same results have also been supported by Barahona and Sánchez-Fortún [5] and Togulga [16]. On the other hand, Artemia species are very resistant to metals and accumulate them without any obvious effect on their life-cycle (Sarabia et al. [13]).
This study is based on a patented device by Portmann et al. [17], which has been redesigned to be more accurate in recording small changes in the mobility of Artemia salina nauplii using a monocular camera and a digital image-processing algorithm. The main hypothesis of this work was that the accumulation of toxic compounds to Artemia organism has a deteriorating effect on its mobility and this deterioration can be measured. Potassium dichromate was firstly tested as a reference substance since it is a widely applied reference toxic compound in aquatic toxicology (Vanhaecke et al. [15]). Later, copper, cadmium, iron and zinc salts were tested for their lethal effect on Artemia salina nauplii. Furthermore, the survivors were also counted and their hypothetical mobility was estimated. Finally, the mobility of the nauplii in those toxic metal samples was recorded and compared to the hypothetical one. The results showed that concentrations of parts per trillion of toxic metals affected the mobility of the nauplii and these changes could be detected consistently using the proposed technique.

2. Materials and Methods

2.1. Preparation of the Test Organisms

Artemia cysts (San Francisco Strain Brine shrimps) were incubated in artificial seawater (ASW) of 3.5% salinity, at 30 °C, pH 8.0 ± 0.5 and under constant aeration for 48 h until they reach the stage of instar II-III. The temperature of the samples throughout the experiment remained at 25 °C. Nauplii from the same generation were applied for each compound.

2.2. Test Chemicals

The reagents were of general laboratory grade unless stated otherwise. Potassium dichromate was provided from BDH (Lutterworth, UK). Copper sulphate [CuSO4·5H2O] and cadmium chloride [CdCl2·H2O] were obtained from Sigma-Aldrich (Gillingham, UK). Copper nitrate [Cu (NO3)2·3H2O] was provided from Fisher Scientific (Loughborough, UK). Zinc sulphate [ZnSO4·7H2O] and iron sulphate [FeSO4·7H2O] were obtained from Acros Organics (Loughborough, UK). Stock solutions of 10,000 mg/L of all reagents were prepared in distilled water and then serial dilutions in ASW were prepared for each metal. The pH of the samples was 8.0 ± 0.5. Macro-cuvettes from polystyrene were used as containers for the toxic samples provided by Fischer Scientific. The same samples of each toxic compound were applied for the assessment of the toxicity using the mortality based assay, hypothetical mobility and mobility assay.

2.3. Further Equipment

A monocular camera (Canon Power shot S3 IS) and a laptop were used to track the movement of the nauplii by recording their activity for two minutes and processing the videos. Light-emitting diodes (LED) torches (AAA battery torch, 7dayshop, Guernsey) were used as illumination source. Subsequently, the captured video sequence was analysed by a digital image processing algorithm that estimates the mobility of the nauplii. The concept has been based on the U.S. Patent of Portmann et al. [17].

2.4. Mortality-Based Assay

The Artemia cysts were cultured in ASW until the stages of instar II-III nauplii (48 h old). Four mL of either ASW (controls) or the tested compound was added to each cell. Then, four nauplii were transferred with Pasteur pipette with the minimal of ASW carried over. Five replicates were performed for the controls and four for every toxicant dilution. After 24 h of incubation, the dead nauplii were counted and the LC50 values estimated with probit analysis. The assay would be considered valid if the mortality percentage of the control does not exceed the 10% (Vanhaecke et al. [11]) and the estimated LC50 of the reference substance (potassium dichromate) ranges between 30 and 50 mg/L (Svensson et al. [6]).

2.5. Hypothetical Mobility of the Nauplii

The main advantage of the proposed approach is that it can quantitatively measure subtle changes in the mobility of nauplii and as a result detect small concentrations of toxic substances. Two minute-videos of five replicates of four nauplii in ASW were recorded and processed through the digital image processing algorithm. In order to calculate the “% hypothetical mobility” of a specific sample, the following equation was applied (Equation (1)).
Biosensors 01 00036 i001
where N24 is the number of the nauplii which remained living after 24 h of exposure to the toxic substance and N0 is the average number of the nauplii initially inserted into the control sample. This approach essentially makes the assumption that alive nauplii have retained 100% of their initial mobility after 24 h in the toxic solutions. In Figure 1, the hypothetical mobility is plotted against the actual mobility of the nauplii. The corresponding “best fit model” equations are displayed on Table 1.
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Figure 1. Percentage of (o) hypothetical and (●) measured mobility (using the camera-based instrument) of the Artemia salina nauplii for Cadmium, Iron, Copper and Zinc ions. The error bars represent the standard error from the four replicates of each concentration.
Figure 1. Percentage of (o) hypothetical and (●) measured mobility (using the camera-based instrument) of the Artemia salina nauplii for Cadmium, Iron, Copper and Zinc ions. The error bars represent the standard error from the four replicates of each concentration.
Biosensors 01 00036 g001
Table
Table 1. Equations from the curves of hypothetical and measured mobility using the “best fit model”.
Table 1. Equations from the curves of hypothetical and measured mobility using the “best fit model”.
CompoundEquation and R2 from %mobility graphsEquation and R2 from %hypothetical mobility graphs
Cadmium chloridey = 0.0008x2 − 0.8406x + 93.713y = −0.00008x2 + 0.0084x + 99.987
R2 = 0.9606R2 = 1
Copper sulphatey = 0.0366x2 − 4.3644x + 81.278y = 0.0452x2 − 5.4572x + 99.97
R2 = 0.9683R2 = 0.9999
Iron sulphatey = 0.0003x2 − 0.3341x + 70.83y = −0.0001x2 + 0.0112x + 99.983
R2 = 0.9267R2 = 1
Zinc sulphatey = 0.0003x2 − 0.3933x + 79.705y = −0.00008x2 + 0.0344x + 96.893
R2 = 0.8493R2 = 0.9336
*NE: Not Estimated.

2.6. Mobility Assay Using Digital Image Processing

Video sequences were recorded for two minutes for all the controls and samples. All the cells were properly illuminated with LED torches. In each video sequence, the nauplii were counted and tracked as illustrated in Figure 2. The % mobility of the nauplii in each sample was estimated according to the following Equation (2):
Biosensors 01 00036 i002
where V24 is the average speed per nauplius in a specific sample after 24 h of exposure to the toxicant as was estimated automatically from the algorithm and V0 is the average speed per nauplius in the control samples.
Biosensors 01 00036 g002 1024
Figure 2. The left image shows a representative video frame as captured by the camera. A sequence of such frames forms the input to the digital image processing algorithm. Although the shrimps are not clearly visible in the cuvette, they can be tracked with good accuracy in order to measure their mobility. The remaining images show some characteristic examples of tracking paths which were derived over 6.6 s intervals. Lighter gray shades denote areas of higher mobility including overlapping tracking paths
Figure 2. The left image shows a representative video frame as captured by the camera. A sequence of such frames forms the input to the digital image processing algorithm. Although the shrimps are not clearly visible in the cuvette, they can be tracked with good accuracy in order to measure their mobility. The remaining images show some characteristic examples of tracking paths which were derived over 6.6 s intervals. Lighter gray shades denote areas of higher mobility including overlapping tracking paths
Biosensors 01 00036 g002
The Effective Concentration (EC50) was estimated through the “best fit model” (Excel, Microsoft Office, 2007). The best fit model revealed that the most appropriate equation was the quadratic equation (Table 1).

2.7. Statistical Analysis

Statistical analysis of one-way ANOVA of the data was performed using Genstat v.12.0 (VSN International Ltd, Hemel Hempstead, UK) and was evaluated at the p < 0.001 level, as presented in Table 2. Furthermore, the 24 h LC50 was determined by using Biostat v.5.2.5.0 (AnalystSoft, 2008). Finally, two-sample t-test was performed for the results obtained from the hypothetical and actual mobility of the nauplii and they were evaluated for their significance at the p < 0.05 level using SigmaPlot v.11.0 (Systat Software, 2008).
Table
Table 2. One-way ANOVA table of the mobility of the nauplii monitored in Cadmium, Iron, Copper and Zinc solutions.
Table 2. One-way ANOVA table of the mobility of the nauplii monitored in Cadmium, Iron, Copper and Zinc solutions.
SubstanceSource of variationDegrees of freedomSums of squaresMean squareVariance ratioF probability
CadmiumConcentrations738,151.75,450.236.19<0.001
Residual243,614.9150.6
Total3141,766.6
CopperConcentrations619,310.03,218.318.68<0.001
Residual213,617.8172.3
Total2722,927.8
IronConcentrations719,541.12,791.623.61<0.001
Residual242,838.0118.2
Total3122,379.1
ZincConcentrations713,469.51,924.28.94<0.001
Residual245,166.1215.3
Total3118,635.6

3. Results and Discussion

The results from the mortality assay of Artemia salina nauplii at the stage of instar II-III were considered valid since the mortality percentage of the controls was 0%. The first experiment regarding the mobility assay was to record samples with ASW and 8 nauplii at time0 and time24. The results from these videos showed that the average speed of the nauplii at five different replicates remained at the same level for 24 h (Table 3). As a result, the movement of the nauplii is not affected by time in controls. This experiment was repeated for every experiment and always the results verified that the mobility of the nauplii remained constant after 24 h. Consequently, the movement of the nauplii was affected only from the existence of toxic compounds.
Table
Table 3. Mobility of Artemia salina nauplii in ASW at time0 and time24.
Table 3. Mobility of Artemia salina nauplii in ASW at time0 and time24.
Time (h)Speed (m/s) per nauplius
00.011444
240.011636
The 24-h EC50 of potassium dichromate was estimated to 36.0 mg/L by the best fit model which is within the limits proposed by Svensson et al. [6].
The toxic effect of Cd2+ was obvious between 102 mg/L where the nauplii retained the 100% of their mobility and 103 mg/L where the nauplii had 25% of the initial mobility (Figure 1). The LC50 was estimated at 710.7 mg/L. The mobility of the nauplii, as evaluated by the camera-based instrument, had better sensitivity since the cadmium toxic effect was detectable at the concentration of 10 mg/L (100% mobility). The EC50 was 54.8 mg/L (Table 4), which is 13 times lower than the LC50 value. Kissa and co-workers [18] have estimated the 48 h LC50 at 159.6 mg/L. Furthermore, the experimental measurements were significantly different from the hypothetical values according to the t-test performed (p < 0.05).
The nauplii were not affected at the concentrations of 10−4–10−1 mg/L and retained 100% of their mobility according to the hypothetical curve in Cu2+ samples. Deterioration of the mobility was observed between 10−4 mg/L and 102 mg/L, 84.1% and 10.9% mobility respectively by the camera-based device (Figure 1). The greater sensitivity allowed the detection of toxic levels even in very low concentrations. Furthermore, the EC50 value (7.6 mg/L) (Table 4) was 2.5 times lower than the LC50 (19.5 mg/L) and 1.3 times lower than the estimated 24 h LC50 of copper (9.5 mg/L) according to Gajbhiye and Hirota [4]. For this toxicant, the camera-based instrument proved more sensitive than the data in the literature and much more accurate than the mortality assay results.
The narrow range of 102 mg/L and 103 mg/L of Fe2+ proved toxic to Artemia salina nauplii according to the hypothetical curve. The LC50 could not be estimated due to extreme results. However, the lowest concentration detected as being toxic using the camera-based instrument was 10−4 mg/L Fe2+, which corresponds to 79.4% of their mobility (Figure 1). The EC50 was estimated at 66.3 mg/L (Table 4). The sensitivity range was extended 106 times by the camera-based instrument comparing to the sensitivity range of the hypothetical curve. Although the 24-h EC50 was higher than the value of 18.2 mg/L determined by Gajbhiye and Hirota [4], the detection range was greater with the camera-based device.
The hypothetical values achieved showed that the Artemia salina nauplii were sensitive to Zn2+ at 102 mg/L and 103 mg/L with 100% and 50% of their initial mobility respectively. By using the camera-based instrument higher sensitivity was achieved. The obtained curve presented a more constant trend with significantly different results from the hypothetical values according to the t-test performed (p < 0.05). The highest value of percentage mobility was observed at 10−2 mg/L corresponded to 88% mobility. The detection of toxic compounds proved successful at very low concentrations (Figure 1). The EC50 was 12.4 times lower (80.5 mg/L) than the LC50 value (1,000 mg/L) (Table 4). Gajbhiye and Hirota [4] evaluated the LC50 for zinc to 17.8 mg/L on Artemia nauplii. The high LC50 value might be due to the small population of shrimps used which lead to the increase of the mortal probability.
Table
Table 4. The LC50 and EC50 values of the tested metals in mg/L as measured for the mortality assay (probit analysis) and camera-based instrument (best fit model).
Table 4. The LC50 and EC50 values of the tested metals in mg/L as measured for the mortality assay (probit analysis) and camera-based instrument (best fit model).
SubstanceLC50 (mg/L)EC50 (mg/L) (±SD)
Cd2+710.754.8 ± 11.1
Cu2+19.57.6 ± 8.3
Fe2+NE*66.3 ± 9.7
Zn2+1,000.080.5 ± 17.1
*NE: Not estimated.
Earlier studies on the toxic effect of heavy metals on the mortality of Artemia species have used very limited ranges in order the LC50 to be specified. For instance, Kissa et al. [18] have used a range of 1 to 200 mg/L. Gajbhiye and Hirota [4] have utilised different ranges dependent on the metal with a minimum of 0.1 mg/L and a maximum of 100 mg/L. Venkateswara et al. [19], who have studied the toxic effect of organophosphates on lethality of Artemia salina, also used a limited range of 0.2 mg/L to 3,000 mg/L dependent again on the tested toxic compound. In this study the EC50 values calculated with high sensitivity by using more extended scales. Moreover, Artemia salina species have been referred as organisms that accumulate toxic compounds with no effect on their life cycle. More specifically, it has been reported by Sarabia et al. [20] that Artemia species are very tolerant to cadmium exposure as mentioned before with LC50 values varied from 93.3 to 280 mg/L. On the contrary, this study has proved that the accumulation of toxic compounds has acute effects on the mobility of the nauplii after 24 h of exposure to the toxicants and this is measurable. This research was performed for quantifying the mobility of the nauplii in very low concentrations, which normally showed no affects in other studies. According to the results achieved this was successfully performed and the system showed high sensitivity detection levels extended to concentrations of parts per trillion.
The software specifications have also minimised the possible errors such as the colour of the solution and the particulate settling to the minimum (Figure 3).
Biosensors 01 00036 g003 1024
Figure 3. The first image shows the solution of 1,000 mg/L Zinc, the second one the iron solution of 1,000 mg/L and the third one Cadmium solution of 500 mg/L.
Figure 3. The first image shows the solution of 1,000 mg/L Zinc, the second one the iron solution of 1,000 mg/L and the third one Cadmium solution of 500 mg/L.
Biosensors 01 00036 g003
Finally, the difference between the LC50 and EC50 values was noticeable in our experimental data. This happened due to the small populations used in the experiments. Using only four nauplii for assessing the mortality in toxic solutions showed very ambiguous results comparing to the results in the bibliography (Gajbhiye and Hirota [4]; Kissa et al. [18]) where the researchers used at least ten nauplii for each sample. In contrast, the mobility of the Artemia salina nauplii could be estimated with good sensitivity using the camera-based device even when the population is very low. Consequently, the calculation of the EC50 values even with small number of nauplii proved possible.

4. Conclusions

The results obtained demonstrate the ability of the system to accurately detect water toxicity in a short period of time and at low cost. The detection of toxic compounds was achieved in very early stages by estimating the mobility of the nauplii in toxic aqueous solutions and compared to the mobility of the organisms in control samples. The camera-based device can provide information about toxic compounds (including metals such as Cu, Cd, Fe and Zn) at a wide range of concentrations from 10−4 mg/L to 103 mg/L. As a toxicity assay this approach is significantly more sensitive than the mortality-based assays, which can only detect concentrations starting from 10−1 mg/L. Furthermore, this study has proved that the accumulation of toxic compounds to Artemia salina nauplii has a deteriorating effect on their mobility. This deterioration was measured with high sensitivity by tracking the nauplii and estimating their average speed using digital image processing. Possible errors of the system achieved to be minimized and more accurate results to be obtained. The most of the findings achieved in this study have been verified from the literature and this leads to a reliable system with high sensitivity in low cost. Thus, this novel approach constitutes a more affordable instrument for promptly detecting toxic substances in aquatic solutions.

References

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MDPI and ACS Style

Kokkali, V.; Katramados, I.; Newman, J.D. Monitoring the Effect of Metal Ions on the Mobility of Artemia salina Nauplii. Biosensors 2011, 1, 36-45. https://doi.org/10.3390/bios1020036

AMA Style

Kokkali V, Katramados I, Newman JD. Monitoring the Effect of Metal Ions on the Mobility of Artemia salina Nauplii. Biosensors. 2011; 1(2):36-45. https://doi.org/10.3390/bios1020036

Chicago/Turabian Style

Kokkali, Varvara, Ioannis Katramados, and Jeffrey D. Newman. 2011. "Monitoring the Effect of Metal Ions on the Mobility of Artemia salina Nauplii" Biosensors 1, no. 2: 36-45. https://doi.org/10.3390/bios1020036

APA Style

Kokkali, V., Katramados, I., & Newman, J. D. (2011). Monitoring the Effect of Metal Ions on the Mobility of Artemia salina Nauplii. Biosensors, 1(2), 36-45. https://doi.org/10.3390/bios1020036

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