Pharmaceutical Products and Pesticides Toxicity Associated with Microplastics (Polyvinyl Chloride) in Artemia salina

Pharmaceutical products, as well as insecticides and antimicrobials, have been extensively studied, but knowledge of their effects—especially those caused by their mixtures with microplastics—on aquatic organisms remains limited. However, it should be borne in mind that the state of knowledge on acute and chronic effects in aquatic organisms for pharmaceuticals and pesticides is not similar. In response, this investigation analyzed the presence of microplastics (polyvinyl chloride) and their impacts on the toxicity of chlorpyrifos (an insecticide) and triclosan (an antibacterial) when they coincide in the environment, alongside the two most consumed drugs of their type (hypolipemic and anticonvulsant, respectively), namely simvastatin and carbamazepine, in Artemia salina. LC50 and cholinesterase enzyme activity were calculated to determine the possible neurotoxicity associated with emergent contaminants in the treatments. The LC50 values obtained were 0.006 mg/dm3 for chlorpyrifos, 0.012 mg/dm3 for chlorpyrifos associated with microplastics, 4.979 mg/dm3 for triclosan, 4.957 mg/dm3 for triclosan associated with microplastics, 9.35 mg/dm3 for simvastatin, 10.29 mg/dm3 for simvastatin associated with microplastics, 43.25 mg/dm3 for carbamazepine and 46.50 mg/dm3 for carbamazepine associated with microplastics in acute exposure. These results indicate that the presence of microplastics in the medium reduces toxicity, considering the LC50 values. However, exposure to chlorpyrifos and carbamazepine, both alone and associated with microplastics, showed a decline in cholinesterase activity, confirming their neurotoxic effect. Nevertheless, no significant differences were observed with the biomarker cholinesterase between the toxicant and the toxicant with microplastics.


Introduction
Currently, aquatic systems, in some cases, show a significant deterioration. Human intervention is one of the sources of water pollution; domestic, industrial and agricultural activities use and produce large quantities of substances such as insecticides, antibacterials, plastics, drugs, etc. This complex mixture of substances with plastics could be responsible for environmental pollution, since aquatic/sediment/soil organisms could be especially exposed [1][2][3]. Plastic waste in the environment is an increasing problem that has generated a lot attention from both researchers and the general public. This debris fragments in the environment into smaller particles, such as microplastics (MP; <5 mm), whose presence has been detected until in the Atlantic gyre [4].
The presence of pharmaceuticals and their metabolites in groundwater, lakes, rivers, oceans and so forth has been confirmed by authors such as Liu et al. (2011) [5], Biel-Maeso Europe. The amount of plastics generated in the world has been growing exponentially for decades, from 348 to 359 million tons during the period 2017/2018 [26].
Some plastic products have a useful life of less than one year, while others have a durability of more than 50 years, but one thing that all of them have in common is that, when their useful life is over, they become waste. The disposal of many of these plastic wastes is not properly managed, so they end up contaminating aquatic ecosystems [27]. Although there are many types of marine debris (e.g., paper, glass and metal), plastics represent 82% of this waste [28]. This plastic garbage can be classified according to its size into macroplastics and microplastics, the latter representing the majority of the total garbage released into the marine environment. As is also the case with pharmaceutical substances, MPs originated by human activity in the form of textile fibers, remains of cosmetics and industrial processes end up in the sewage system and reach the marine environment through the effluents of WWTPs, where they are not completely eliminated [29][30][31].
They can also act as vectors for the transportation of other pollutants, because they have additives in their composition that can be released into the environment during the fragmentation process and they have the ability to adsorb other chemical pollutants on their surfaces, including heavy metals [32], hydrophobic organic pollutants and pharmaceutical compounds [33]. From this capacity of MPs to act as vectors for other contaminants derives the importance of investigating the interaction between MPs, pharmaceutical compounds and pesticides, as these contaminants are increasingly present in aquatic ecosystems. Authors such as Rainieri et al. (2018) [34] and Webb et al. (2020) [35] have shown that the presence of MPs in the environment affects the toxicity of other pollutants.
Cholinesterase (ChE) activity inhibition is one of the biomarkers of exposure, which is widely used and recognized as a biomarker to organophosphate compounds, such as CPF [36], as well as to pharmaceutical substances. In crustaceans, Thi et al. (2009) [37] showed that the cholinesterase activity present in adult Penaeus monodon was inhibited by the action of antibiotics. Albendín et al. (2021) [38] and Soto-Mancera et al. (2020) [39] determined a decreased level of cholinesterase activity exposed to organophosphate compounds in seabream. Nunes et al. (2016) [40] found that the anxiolytic diazepam inhibited the cholinesterase activity present in Artemia parthenogenetica. Similarly, Yu et al. (2018) [41] determined that MPs significantly reduced cholinesterase activity in Eriocheir sinensis.
Relative to fish and molluscs, the use of Artemia salina in toxicity tests has many advantages. These crustaceans have a shorter life cycle, provide available populations all year and offer both a standardized method of cultivation from dried cysts and easy handling. Therefore, Artemia salina has been successfully used in toxicological tests for decades [42][43][44].
For the above reasons, in this study, the impacts of the toxicity of MPs (polyvinyl chloride), pharmaceutical substances (simvastatin and carbamazepine) and pesticides (chlorpyrifos and triclosan) on Artemia salina were evaluated, in order to determine whether MPs in combination with drugs or pesticides increase the adverse effects on this organism. To measure possible adverse effects, toxicity tests were performed by determining the LC 50 , as well as the ChE, activity.

. MP Intake Bioassay
A. salina specimens were exposed to nominal concentrations of 0.26, 0.69 and 1.6 mg/dm 3 of polyvinyl chloride in seawater, in 25 mL flasks, with each containing 10 adults. These concentrations were selected based on the results obtained by other authors [45,46]. Three replicates of each concentration, as well as a control concentration, were used. The tests were conducted according to the guidelines of the Organisation for Economic Co-operation and Development (OECD) chemical test guideline 202 [47], testing the dead/immobilization of A. salina. To reach the stable microplastic concentrations, a stock suspension of microplastics was added, previously stirred. MP concentrations were not quantified. After the 48-h test period, a visual analysis of the digestive system of the organisms exposed to the MP was observed under an optical microscope to check whether the specimens had ingested MP.

Pesticides, Pharmaceutical Products, MPs and Reference Toxicity Test
Potassium dichromate (K 2 Cr 2 O 7 ) was used as a reference test. The concentrations used were 80, 40, 20, 10, 5, 2.5 and 1.25 mg/dm 3 , as well as a seawater control. Glass flasks of 25 cm 3 were used. There were 3 replicates for each treatment and 10 organisms in each flask. The exposure duration was 48 h at 21 • C and 16 h of light/8 h of darkness. A. salina were not fed. At the end of the test, the surviving individuals were counted; if they did not show any movement, they were considered dead. The concentrations of simvastatin and carbamazepine were 12.03, 10.03, 8.35, 6.96, 5.80 and 52.08 mg/dm 3 ; and 43.40, 36.17, 30.14 and 25.16 mg/dm 3 in seawater, respectively. Following these tests, the concentrations of triclosan and chlorpyrifos were 12, 6, 3, 1.5, 0.75 and 0.0312 mg/dm 3 ; and 0.0156, 0.0078, 0.0039 and 0.00195 mg/dm 3 , respectively.
The nominal MP concentration 0.26 mg/dm 3 was chosen based on a bibliographic review [45] and was considered environmentally relevant. Acetone was used as the solvent due to the hydrophobic nature of chemical compounds. A control with seawater and another with acetone were used in all the tests. Eight semi-static toxicity tests with three replicates were undertaken: simvastatin, simvastatin-MP, carbamazepine, carbamazepine-MP, TCS, TCS-MP, CPF and CPF-MP. Ten specimens of Artemia salina (aged 4 weeks) of approximately 8 mm of size were included in each flask. The solvent concentration in the acetone control and chemical component-only exposures was <0.001% v/v. In the MP tests, the polyvinyl chloride stock suspension (0.26 mg/dm 3 ) was added.
Surviving and dead/immobilized organisms were counted. Surviving A. salina specimens were preserved frozen at -80 • C, until the time of analysis. In addition, before conservation, living organisms from the tests with MPs were observed under an optical microscope to check whether they had ingested the MPs.

Sample Preparations
After euthanasia by ice, the samples were stored at -80 • C until processing. The surviving A. salina from each concentration were rapidly thawed and homogenized cold at the rate of 100 µL of phosphate buffer (0.1 M pH 7.4), using an Ultraturrax homogenizer and centrifuged at 9000 g for 30 min at 4 • C. The supernatants of each sample were then collected. The protein content of the samples was measured using Bradford's (1976) [50] method, adapted to microplates using bovine serum albumin as the standard. All enzyme and protein determinations were prepared in triplicate at 25 • C. ChE activities were expressed as nmol hydrolyzed substrate/min/mg of protein. The specific activities are reported below as the mean ± SD.

Data and Statistical Analysis
The mortality data were treated with the program of the Environmental Agency of the United States (EPA-USA), probit method. The values of CL 50 for all the chemical compounds individually and associated with the MPs were studied.
Cholinesterase activity data were statistically analysed using the IBM SPSS Statistics (IBM, Madrid, Spain) for Windows Version 23 program. Assumptions regarding the data's normality and homogeneity of variance were tested by using the Shapiro-Wilk test and Levene's test, respectively. When the assumption of normality was not satisfied, the Kruskal-Wallis test was used to determine whether there was any significant difference and the Tukey or the Mann-Whitney U test was used to determine between which groups there was a significant difference. Statistical differences between groups were accepted for p-values lower than 0.05.
When the assumption of normality was followed, a one-way analysis of variance (ANOVA) was employed to assess the differences of AChE activity among the different chemical compounds, followed by Dunnet's post hoc comparison test.

Toxicity Reference Test
The LC 50 value of K 2 Cr 2 O 7 during the 24-h duration of the test was 11.80 mg/dm 3 . The values obtained for the lower and upper confidence limits, both of 95%, were 8.75 and 16.07 mg/m 3 , respectively.
The database of the State Agency for the Protection of the Environment (EPA) has established that the LC 50 value for this toxic substance in acute toxicity tests on invertebrates should be in the range of 0.067-59.90 mg/dm 3 . When the value obtained for K 2 Cr 2 O 7 was found, i.e., LC 50 of 11.80 mg/dm 3 , which is within this range, it was determined that the quality of the A. salina population was optimal for carrying out subsequent tests with the substances.

Toxicity Test: Pharmaceuticals, Pesticides and MPs
In Figure 1, the samples of MPs and digestive tract of A. salina in the control group are observed. Artemia salina ingested MPs during the 48 h exposure experiments at all the concentrations exposed (0.26, 0.69 and 1.5 mg/dm 3 ; Figure 2), as particles were detected in the digestive tract. These nominal concentrations were used to check whether the MPs indeed accumulated in A. salina. In the subsequent tests, the lowest concentration was used, so it can be considered ecologically relevant [51].  The organisms that had ingested MPs were counted. No mortality was recorded in any of the concentrations or in the seawater control during the test. The number of A. salina with MPs increased with concentration (Table 1). In the lowest concentration used, 16.6% of individuals had ingested MPs. MPs were found in the digestive tract of the surviving A. salina of the simvastatin and MP test; these were detected in 58 of the 127 specimens exposed to MPs that survived. In the carbamazepine and MP test, these were found in 71 of the 130 that survived. Meanwhile, in the CPF + MP and TCS + MP test, these were not observed.
The mortalities recorded in tests where organisms were exposed to different increasing concentrations of simvastatin, simvastatin-MP, carbamazepine, carbamazepine-MP, TCS, TCS-MP, CPF and CPF-MP, as shown in  The toxicity acute test showed lower mortality in organisms exposed to simvastatin and MP together compared to simvastatin alone. At the lowest concentrations (5.80 and 6.96 mg/dm 3 ), the mortality difference was slightly smaller in this test, becoming more marked in the concentration of 8.35 mg/dm 3 . At the highest concentrations (10.03 and 12.03 mg/dm 3 ), the difference in mortality between the two assays was greatest, being 10% in both concentrations. In the visual controls that were carried out during both tests, no alteration was observed, neither in the physiology nor in the behavior of the organisms. The same mortality rates (10% and 16.66%, respectively) occurred in A. salina exposed to concentrations of 25.16 and 30.14 mg/dm 3 in the tests with carbamazepine only and carbamazepine associated with MPs. The greatest mortality difference (10%) between the treatments occurred in the concentration of 52.08 mg/dm 3 of carbamazepine.
The organisms did not manifest changes in physiology, even though they did in their behavior. A. salina survivors at concentrations of 30.14 and 36.17 mg/dm 3 in both assays exhibited slow mobility with respect to the control, including alternating periods of immobility with periods of fast swimming movements with respect to the control. At the highest concentrations of 43.40 and 52.08 mg/dm 3 (carbamazepine and carbamazepine + MP), A. salina did not show mobility and only reacted when mechanically stimulated with a glass rod.
Comparing the CPF treatments with and without MP, at the lowest concentrations (0.00195 and 0.0039 mg/dm 3 ), we see that the percentage of mortality was lower in the chlorpyrifos test versus chlorpyrifos and associated MP, but at higher concentrations (0.0078 and 0.0156 mg/dm 3 ), the pattern changed, mortality being lower for chlorpyrifos and MP. At the concentration of 0.0312 mg/dm 3 , there was 100% mortality in both tests.
The mortality at 0.75 and 1.5 mg/dm 3 did not differ in the triclosan test with and without MP. At a concentration of 12 mg/dm 3 , there was 100% mortality in both tests.
In general, at the highest concentrations, mortality was slightly lower in tests where the toxicant was associated with MP, but they were not statistically different.
According to the OECD guide [47], the mortality of controls cannot exceed 10% in order for the test to be considered valid. Given that none of the four tests performed in this study exceeded this percentage, they could be regarded as such.
The LC 50 values and 95% confidence intervals for A. salina exposed to the different substances are presented in Table 2.

Enzymatic Assay
The results regarding cholinesterase activity in simvastatin, carbamazepine and both in association with MP are shown in Figure 4. In the test with carbamazepine, statistically significant differences were obtained between the seawater and acetone controls at concentrations of 36 In the tests with carbamazepine + MP, an increase in the inhibition of cholinesterase activity was observed versus only with carbamazepine treatments. After statistical analysis of the data, statistically significant differences were obtained between the controls for seawater, acetone and all concentrations of MP-associated carbamazepine that were used in the test. MPs showed significant differences with concentrations of 25.16, 30.14, 36.17, 43.40 and 52.08 mg/dm 3 . These differences were also determined between the concentration of 36.17 mg/dm 3 and those of 25.16 and 30.14 mg/dm 3 , between the concentration of 43.30 mg/dm 3 and those 25.16 and 30.14 mg/dm 3 and between the concentration of 52.08 mg/dm 3 and 25.16 and 30.14 mg/dm 3 .
In addition, the results obtained between the same concentrations of both assays were compared (simvastatin and MP associated with simvastatin), revealing no statistically significant differences.
The results of cholinesterase activity in CPF, TCS and either in association with MP are shown in Figure 5. The concentration value of 0.008 mg/dm 3 CPF was considered abnormally high (possibly due to biological variability), so this result is disregarded in the Discussion section below. Statistically significant differences in CPF + MP treatments were observed between the MP and the controls, between the concentrations of 0.004 mg/dm 3 and the 0.008 mg/dm 3 + MP, between 0.002 mg/dm 3 and 0.004 mg/dm 3 and 0.008 mg/dm 3 + MP concentration, and between 0.002 mg/dm 3 + MP and 0.008 mg/dm 3 + MP.
No differences were observed between equal concentrations of 0.002 and 0.004 mg/dm 3 CPF with and without MP.

Discussion
Pesticides, pharmaceuticals and MPs are environmental contaminants whose hazardous potential (especially in the case of the latter) have been ignored until relatively recently. Nevertheless, they can have direct effects on organisms, as well as act as vectors of other pollutants, potentially modifying their toxicity and bioavailability [32,33]. In this study, we observed the variability of responses between different pollutants with and without MP in the crustacean A. salina.
Among the values obtained for LC 50 , simvastatin was found to be most toxic (LC 50 of 9.348 mg/dm 3 [53] observed a 96-h LC 50 of 1.18 mg/dm 3 for larvae of Palaemonetes pugio and more than 10 mg/dm 3 for adult specimens of the same species, a value that was very similar to that obtained for A. salina (9.348 mg/dm 3 ). In fish, Ribeiro et al. (2015) [54] studied the effects of simvastatin on zebrafish (Danio rerio), establishing an LC 50 of 5 mg/dm 3 for zebrafish embryos. Another study carried out by Key et al. (2009) [55] determined an LC 50 of 2.68 mg/ dm 3 for Fundulus heteroclitus.
In A. salina, statistically significant differences were not recorded between the measures of cholinesterase activity in the control groups and the groups exposed to the different concentrations of simvastatin and simvastatin associated with MP tests. Similar results were observed by Key et al. (2009) [55] regarding simvastatin exposure for 96 h in Fundulus heteroclitus, although reduced cholinesterase activity declined slightly, if not significantly. In crustaceans, the test carried out by Key et al. (2008) [53] showed an LC 50 of simvastatin in the range of 0.001 to 10 mg/dm 3 , which did not cause alterations in the acetylcholinesterase activity of larvae and adults of the shrimp Palaemonetes pugio. Considering that simvastatin is a commonly used and highly prescribed drug whose discharge into the aquatic environment has increased in recent years, it is reasonable to expect that its presence in the environment tends to increase and consequently enhance the risk of undesirable effects on the most sensitive species. For this reason and given this study's results, it is advisable to continue investigating the sublethal effects that this drug can cause, carrying out trials with other taxa and with organisms at different stages of development, using different biomarkers to assess the possible effects produced and increasing the time of exposure to the drug through chronic toxicity tests.
In the case of carbamazepine, the 48-h LC 50 50 of 77.7 mg/dm 3 in the same organism. These concentrations differ from those obtained in this work; hence, A. salina seems to be a more sensitive organism to carbamazepine than Daphnia magna. For the association of carbamazepine with MP, an LC 50 of 46.503 mg/dm 3 was obtained, which was higher (by 3.303 mg/dm 3 ) than carbamazepine alone. A similar pattern was obtained with simvastatin. Besides, we observed that toxicity decreased in the combination of pharmaceuticals and MP. However, Brandts et al. (2018) [58] determined that exposure to carbamazepine associated with nanoplastics (polystyrene) induced a significant negative regulation in genetic expression in Mytilus galloprovincialis compared to exposure to carbamazepine only. In addition, studies carried out by Gambardella et al. (2017) [59] showed that exposure to MP (polystyrene) caused neurotoxic effects in nauplii of Artemia franciscana and Amphibalanus Amphitrite. Moreover, the ChE activity in carbamazepine and carbamazepina + MP exposed to A. salina was significantly inhibited in our study. Similar results have been obtained by other authors with different species of invertebrate organisms. For instance, Siebel et al. (2010) [60] observed via an in vitro test that carbamazepine inhibited acetylcholinesterase activity in the brain of zebrafish (Danio rerio). In crustaceans, Nkoom et al. (2019) [61] reported a significant decrease in acetylcholinesterase activity in Daphnia magna specimens exposed to concentrations of 5 and 100 µg/L, as well as an ability to bioconcentrate in the aqueous medium under laboratory conditions. The ChE activity recorded in this test (carbamazepine + microplastic) was slightly lower than that obtained in the isolated carbamazepine test, but no statistically significant differences were obtained using the same concentrations in the two tests.
On the other hand, the smaller LC 50 values from lowest to highest were: CPF, CPF + MP and finally TCS + MP and TCS, which were similar. The value of 48-h LC 50 50 of 0.0048 mg/dm 3 in a test with the crustacean Penaeus vannamei (juveniles) exposed to CPF. Varó et al. (1998) [67] exposed to CPF on nauplii of different species of the genus Artemia sp. and observed differences in sensitivity to the toxic substance, indicating that the most sensitive species was Artemia salina (24-h LC 50 from 0.95 to 5.12 mg/dm 3 ). They also described differences that were not only based on the species tested (A. salina, A. persimilis, A. franciscana and A. parthenogenetica), but also between strains of the same species. Accordingly, these authors exposed to CPF in Artemia parthenogenetica, adult fish Gambusia affinis and Aphanius iberus and observed increased resistance to CPF in the genus Artemia compared to the two fish species (48-h LC 50 for G. affinis of 0.5 mg/dm 3 and 48-h LC 50 for A. iberus of 0.0386 mg/dm 3 ). In addition, the genus Artemia showed different sensitivity to the toxic substance according to the degree of development or intraspecific variability (nauplii 24-h LC 50 : juveniles, 3.9 ± 0.9 mg/dm 3 ; adults, 0.08 ± 0.01 mg/dm 3 ).
Baek  [67] findings. In the same study, acetylcholinesterase activity was studied, comparing newborn nauplii with 48-h nauplii. The former was found to exhibit a greater decrease in cholinesterase activity than the 48-h nauplii, following exposure to CPF for 24 h, rendering this a very useful marker for predicting signs of contamination by this toxic substance in the environment. The data from these studies indicate that there are differences in sensitivity, not only among species, but also depending on the stage of development. Adults and juveniles seem to be more sensitive than nauplii, so the choice of biomarker and developmental stage is of great importance in experiments to ensure a higher safety range. In our study, the LC 50 data regarding A. salina were more in line with the values provided by these authors working with adults and juveniles.
The association of CPF with MP was not reflected in an increase in toxicity with CPF, as the LC 50 value was higher. This toxicity-reducing effect has been mentioned by other authors [18], who have indicated that CPF adsorption to MP can reduce toxicity's effect on algal growth (Isochrysis galbana).
On the other hand, we observed a significant decrease in cholinesterase activity by the CPF + MP test, just as Oliveira et al. (2013) [69] and Luís et al. (2015) [45] found that acetylcholinesterase activity in samples of Pomatoschistus microps exposed to MP (polyethylene) to a 96-h test was lower than in a control. However, in the TCS + MP test, no significant differences were found, as has also been described by other researchers working with aquatic organisms [64,70].
Organophosphate substances (CPFs) are known as prototype inhibitors of this enzyme. In fact, the specific activity of cholinesterase in A. salina decreases as concentrations of CPF increase [67]. Nevertheless, in this work, no statistically significant differences in cholinesterase activity were observed between equal concentrations of CPF with and without MP.
The results obtained indicate that the presence of MP in the medium reduces the toxicity, considering the LC 50 values that may be related to the low MP intake detected in our preliminary test, since the concentration used (0.26 mg/dm 3 ) was lower. This concentration was related to the concentration of MPs observed in the environmental. However, inhibition of cholinesterase activity of A. salina exposed with CPF, simvastatin and CPF + MP, simvastatin + MP in a concentration-dependent ratio showed a synergistic effect of MP+ other contaminants, probably due to their possible role as vehicles of exposure. Eder et al. (2021) [71] reviewed studies showing that the toxicity of pharmaceuticals and other particles and chemicals increased when exposure was combined with MP. Among the adverse effects, they distinguished the same biomarker studied in our work, the inhibition of cholinesterase activity. The synergistic effect could be determined by the sorption behavior of organic contaminants to MP that, according to Wang et al. (2020) [72], are partitioning, surface sorption and pore filling, as well as by the properties of the MP, organic contaminants and aquatic conditions. Thus, the interaction of MPs with contaminants can result in aggregation, reduced bioavailability and alteration in the toxicity to the organism [73].

Conclusions
In this study, the adverse effects of pharmaceutical compounds with associated MPs and pesticides with associated MPs were studied. Regarding 48-h LC 50 in A. salina, the MPs did not potentiate the adverse effects of pollutants when they were co-exposed; however, cholinesterase activity decreased more if the pollutant (drug or pesticide) was in contact with the MP than without them, indicating a cellular effect.
The concentration of MP exposed to A. salina was used by other authors for ecologically relevant studies, but the preliminary studies in this work with MP ingestion by organisms showed that, if the concentration of MP increased, the number of A. salina that incorporated MPs also increased, and this could suggest, that if the MP concentration increases in the environment, toxicity in the organism can also increase.

Institutional Review Board Statement: Not applicable.
Informed Consent Statement: Informed consent was obtained from all subjects involved in the study.