1. Introduction
The use of nanoparticles of titanium dioxide (nTiO
2) has increased significantly in recent years. It has been predicted that the global market for nanotechnology products would achieve 3 trillion
$ by 2020 [
1]. Piccinno documented the estimated worldwide production of titanium dioxide nanoparticles (nTiO
2) at approximately 5000 t/year in 2006–2010 and 10,000 t/year in 2011–2014 with an increase in the production of this nanomaterial by 2025 [
2].
This impressive increase is mainly due to the demand for this metal oxide in the paper, paint, coating, cosmetics, food, and plastic industries. TiO
2 is a white substance commonly used as a whitening or brightening agent that is generally synthesized in different crystalline forms, mainly anatase and rutile. It is also used in water purification processes due to the high photocatalytic activity showed by specific nTiO
2 formulations such as the well-known Degussa P-25, which contains anatase and rutile phases in a ratio of about 3:1 [
3].
Nano-size TiO
2 is increasingly used as a mineral sunscreen to protect the skin from both ultraviolet light A and ultraviolet light B radiation, because of its broad UV spectrum-attenuation characteristics. When it is formulated in nano-size, the protection significantly improves as only a tiny proportion of UV rays can pass through the sunscreen film without hitting a particle [
4,
5,
6]. It is expected that commercial sunscreens contain a mixture of physical and chemical UV filters to produce a broader spectrum of protection [
7].
After use, nTiO
2 is discharged into the sewage system and subsequently released into surface waters, where it can interact with living organisms [
8]. As both solar irradiance (i.e., the amount of sunlight received by Earth’s surface) and nTiO
2 accumulation in the environment increase year after year, there is a high probability that UV radiation and nTiO
2 interact in the aquatic environment. This fact, in turn, increases the concerns about the environmental fate and ecotoxicity of this compound [
9]. The process of nTiO
2 activation by UV light and subsequent formation of reactive oxygen species (ROS), such as superoxide radicals (O
2•‒), hydroxyl radicals (
•OH), and singlet oxygen (
1O
2) in water is relatively well known [
10,
11,
12]. However, in the presence of high concentrations of salts, as is the case in seawater, the mechanisms driving their interaction are still not fully understood although there is some evidence that reactive halogen species (RHS) may be produced [
13,
14]. ROS and RHS can cause oxidative stress to cells in the aquatic environment [
15], hence damaging cell membranes and oxidizing proteins [
16].
Previous studies have shown the phototoxic effects on
D. magna and
Artemia sp. simultaneously exposed to nTiO
2 and radiation [
17,
18].
In the present study, the combined effect of nTiO2 and simulated solar radiation towards two aquatic organisms, i.e., D. magna and A. sp. as a proxy of freshwater and seawater organisms, respectively, was investigated and the EC50 were calculated. In addition, Artemia sp. was exposed to a mixture of organic UV filters, nTiO2, and UV solar radiation to identify the toxicity dynamics.
3. Phototoxicity Experiments
3.1. Daphnia magna Bioassays
The exposure procedure was adapted from the 48 h acute toxicity test using D. magna according to US Environmental Protection Agency (USEPA) standard operating procedure 2024.
The SSR experiments were conducted using a solar box equipped with a pulsed-light 1500 W Xenon lamp emulating the solar light spectrum, and an air-driven cooling system to adjust the temperature during irradiation. A glass filter located between the light and the irradiated plates served to cut off radiation with λ < 290 nm, thus filtering the ultraviolet light C radiation component emitted by the lamp, which is not characteristic of the sunlight arriving at the Earth. Petri dishes with 10 mL of the medium containing 10
D. magna individuals and nTiO
2 were placed inside the solar box. The UV light fluence rate was determined to be 10.67 W/m
2 in the range 290–400 nm, using
o-nitrobenzaldehyde actinometry, according to Bustos [
21].
Assays were conducted varying both the SSR time, 16 and 48 h, as well as the concentration of nTiO
2 i.e., 0 (control), 0.000018, 0.01, 0.1, 1, and 10. These concentration levels were selected considering the highest reported nTiO
2 concentrations in water in Europe, according to Gottschalk [
22]. Besides, we considered a higher concentration of 100 mg/L, to potentially observe enhanced toxic effects. Control samples in the absence of nTiO
2 and UV light exposure were also tested in all the experiments.
The bioassays were carried out in duplicate. The organisms were not fed during the experiments. All test solutions were kept at 20 ± 2 °C during the exposure period. D. magna immobilization was recorded after 48 h. At the end of the exposure, the number of individuals showed mobility in each recipient, and it was registered. The data obtained were used to determine the EC50 values.
UV exposure was conducted placing the organisms to a distance of 30 cm from the UV lamps, for a time interval of 16 and 48 h. The exposure was made in Petri dishes containing the organism and the respective culture media. A control group was kept in the same room but without exposure to the UV radiation.
A preliminary test was carried out to assess the behavior of D. magna exposed to SSR, and to check the feasibility of the following tests.
3.2. Artemia sp. Bioassays
Exposure tests for Artemia sp. were carried out according to the Organisation for Economic Co-operation and Development 2004 (OECD ), using the same exposure protocol conducted for D. magna. A group of approx. 30 A. sp. individuals were placed in individual containers and exposed to various concentrations and SSR in 96 h period test (3 replicates). Mortality was the endpoint of the test. Control samples without nTiO2 and UV light exposure were tested in all the experiments and was kept in the same room.
The simulated UV radiation experiments were conducted in the same solar box used for D. magna testing. Plates with salty media containing 30 Artemia sp. individuals and 2 mL of organism media and nTiO2 were placed inside the equipment. Assays were conducted varying both the UV irradiation time, 16 and 48 h, as well as the concentration of nTiO2 i.e., 0 (control), 0.000018, 0.01, 0.1, 1, 10, and 100 mg/L.
UV exposure was conducted placing the organisms to a distance of 30 cm from the UV lamp, for a time interval of 16 and 48 h. The exposure was made in Petri dishes containing the organism and the respective culture media. A control group was kept in the same room but without exposure to the UV radiation.
All test solutions were kept at 20 ± 2 °C during the exposure period. A. sp. immobilization was recorded after 96 h. In all Artemia sp. bioassays, the organisms were not fed during the exposure.
Since
Artemia sp. in the first trial was resistant to the effects of nTiO
2 in conjunction with SSR, it was decided to experiment with mixtures of the most used and most toxic compounds in sunscreens [
23,
24], in addition to exposing this organism to SSR.
Then, a second experiment was carried out, exposing Artemia sp. to nTiO2 in a mixture with the organic UV filters, BP3, EtPABA, and OC. These compounds were selected because they are commonly used in combination with nTiO2 in personal care products with sunlight protection. Exposure experiments containing 2 mL of organism media and 30 Artemia sp. individuals were made in triplicate in Petri dishes.
Finally, a third bioassay was carried out where Artemia sp. was exposed to increasing concentrations of nTiO2, i.e., 0 (control), 0.000018, 0.01, 0.1, 1, 5, 10, and 100 mg/L, for 48 h. The controls were (i) a solution not irradiated, (ii) a solution with the mixture of organic UV filters, and (iii) an organism’s medium solution). Exposure experiments containing 2 mL of organism medium and 30 Artemia sp. individuals were made in triplicate.
4. Results
4.1. Phototoxicity of nTiO2 towards D. magna
A preliminary test was conducted in Petri dishes in 10 mL of the medium containing 10 D. magna individuals (2 replicates) and was classified into two groups, the control group (A), and the group exposed to SSR (B). Both groups were exposed 24 h before the assay started with three concentrations of nTiO2 (0 (control), 0.1, 1, and 10 mg/L). Immediately after the 24 h doping, group A was incubated 6 h dark cycle, whereas group B was irradiated during the same time.
After UV light exposure of group B, the media in A and B were renewed, and acute toxicity tests (48 h exposure time) were conducted as described in
Table 1.
The results of the preliminary test showed, on the one hand, that the low acute toxicity of nTiO2 towards D. magna suggested ingestion and accumulation, since only <23% of immobilization at the 10 mg/L concentration was observed. At lower concentrations, i.e., 0.1 mg/L < 15% of immobilization was observed.
In contrast, D. magna was exposed to the combined effect of nTiO2 and UV radiation, the toxicity increased to 30% of immobilization with 10 mg/L nTiO2, at 0.1 mg/L the immobile individuals raised to 24%.
It was clear that nTiO
2 concentrations were harmful to
D. magna, as in previous works when
D. magna was exposed to nTiO
2 [
25,
26,
27].
Figure 1 shows that the immobilization ratio was 24% when
D. magna was exposed to nTiO
2 (group A), still, when this organism was exposed to both nTiO
2 and SSR (group B) immobilization ratio was low, 30%, suggesting a joined effect.
Given that the immobilization percentage increased in group B compared to group A, this provided the information needed to design the following bioassays.
In the second bioassay, D. magna was co-exposed to nTiO2 and SSR for 16 h and then kept in darkness for 8 h (mimicking a full solar day) before the acute toxicity test measurements. The exposure was made in Petri dishes containing 10 mL of the medium and 10 D. magna individuals. After 48 h exposure, the mobility in the control groups exceeded 90%, in both cases: in the absence of UV radiation and nTiO2.
The results showed that the toxicity of nTiO
2 towards
D. magna increased with increased nTiO
2 concentrations. As shown in
Figure 2, at the lowest concentration (0.000018 mg/L), the mortality rate after 24 h was low, 20% a ratio of immobilization. At 10 mg/L nTiO
2, the mortality rate increased up to 60% with an EC50 value of 6.4 mg/L. In the presence of SSR, the toxicity of nTiO
2 to
D. magna increased, suggesting that higher phototoxicity is displayed when the concentration of nTiO
2 is high, which is in agreement with the results found when
D. magna was only exposed to increasing nTiO
2 concentrations. The results evidenced a concentration-dependent immobilization process.
In the third set of bioassays, D. magna was exposed in Petri dishes containing 10 mL of the medium and 10 D. magna individuals. The organisms were exposed to increasing concentrations of nTiO2 (0 (control), 0.000018, 0.1, 1, 10, and 100 mg/L) and 48 h of UV radiation. In this bioassay, after the 24 h exposition, the irradiation was stopped for a few minutes to measure the immobilization. Then, the irradiation continued for an additional period of 24 h. Hence, the total exposure time was 48 h.
At the first 24 h of exposure, we observed that at 0.1 and 1 mg/L nTiO2, the immobilization was <20%. Still, at 10 mg/L the immobilization increased to 42%, and at the highest concentration, 100 mg/L, 75% of the individuals were immobile. Under these experimental conditions, the estimated EC50 was 12.98 mg/L.
After 48 h exposition to continuous UV radiation, the immobilization at the two lower concentrations of nTiO
2, 0.1, and 1 mg/L was 40%. At 10 mg/L the immobilization was 77%, and at the highest concentration, 100 mg/L, 100% of immobilization was observed. In this case, the estimated EC50 was 5.50 mg/L, a relatively lower value than that calculated at the first 24 h UV irradiation, as shown in
Figure 3. In all the acute toxicity tests with
D. magna, survival in the control groups exceeded 90% after 48 h exposure.
4.2. nTiO2 Phototoxicity towards Artemia sp.
Artemia sp. was exposed to different concentrations (0 (control), 0.000018, 0.1, 1, and 10 mg/L) of nTiO2 and 16 h SSR and 8 h dark cycle. The toxicity under these conditions towards Artemia sp. was null.
As
Artemia sp. habits in salty and hypersaline environments, it can quickly adapt to variations in salinity, ranging from 70% to 300%, as stated by Amat et al., in 1983, the above allows the specimen to successfully face environmental adversities under extreme conditions. Given this characteristic, it was decided to combine nTiO
2 with some organic UV filters (
Table 2) because, in most sunscreens’ formulations, a mixture of them is used. This mixture of UV filters, organic and inorganic substances, occurs in marine environments and could trigger different or similar toxicity mechanisms towards organisms as
Artemia sp. [
28].
The concentrations of nTiO
2 selected for this bioassay were 0.000018, 0.1, 1, and 10 mg/L. Then from the solution containing BP3, OC, and EtPABA, we prepared solutions of 0.01, 0.1, 1, and 3 mg/L, and mixed them with nTiO
2 (
Table 2). The lowest concentrations of nTiO
2 and the UV filters were combined in Mix 1, while in Mix 2 and Mix 3 the concentrations were equal for nTiO
2 and UV filters. Finally, the two highest concentrations were mixed in Mix 4.
At the first 24 h of exposure, Artemia sp. showed immobilization <20%, even when exposed to the Mix 4, corresponding to the highest concentrations of nTiO2 and organic UV filters.
As shown in
Figure 4, the lethal effects were recorded at 96 h, the time set in the OECD, 2004.
Artemia sp. showed an immobilization ratio under 20% in Mix 1. Still, in Mix 2 and Mix 3, the immobilization remained from 16% to 23%. However, with Mix 4, the immobilization increased up to 35%. Under 16 h SSR, concentration-dependent immobilization in
Artemia sp. was observed after 96 h exposure (
Figure 4), and the EC50 value was 52 mg/L.
In the second bioassays, the Artemia sp. was exposed to nTiO2 and SSR, like as the third assay with D. magna (nTiO2 concentrations of 0 (control), 0.000018, 0.1, 1, 10, 100 mg/L, and 48 h UV radiation exposure). The Artemia sp. immobilization was then calculated at both 24 h and 48 h of irradiation with the presence of nTiO2 in the medium.
After the first 24 h and at concentrations of 0.1 and 1 mg/L nTiO2, low immobilization was detected, <10%. Still, at 10 mg/L nTiO2, immobile individuals were 20%, and for 100 mg/L immobilization of 30% was observed. The calculated EC50 was 62.33 mg/L.
Then, after 48 h of UV radiation, a notable increase of the immobilization was observed (
Figure 5), at 0.1 mg/L was 55%. At 1 and 10 mg/L nTiO
2 concentrations, the immobilization remained <80%, but almost 98% immobility was registered at 100 mg/L, corresponding to a EC50 value of 7.60 mg/L.
In all the acute toxicity tests with Artemia sp., survival in the control groups exceeded 90% after 48 h exposure.
5. Discussion
Two aquatic organisms,
Daphnia magna and
Artemia sp. were exposed to the combined effect of nTiO
2 and SSR. The results showed that the toxicity of nTiO
2 increased with UV light to the tested aquatic organisms (freshwater or seawater). The process of nTiO
2 activation by UV light and subsequent formation of ROS in pure water is currently relatively well known [
29].
Since nTiO2 are metal oxide nanoparticles, they are not biodegradable so will not lose their toxic properties but will persist in the environment. The nTiO2 form aggregates in aqueous environments; primary size aggregates can settle down and remain immobilized, while others are dispersed and become more mobile, bioavailable, and toxic. On the other hand, interaction with other particles and suspended organic matter is also supposed to modify their dynamic properties, and therefore, alter their toxicity.
So far, it has not been possible to predict the environmental or biological impacts of nTiO2 due to the complexity of the marine aquatic ecosystem, since in freshwater the behavior is different than in saltwater in terms of the aggregates that may form. It is known that in conventional wastewater treatment plants, the removal of these nanoparticles is not carried out due to their small size, which allows them to escape from conventional filters and membranes. Furthermore, the removal of nTiO2 through sedimentation is not viable. Nevertheless, the removal of the nTiO2 can be accomplished through ultrafiltration/nanofiltration, achieving 95% removal efficiency.
Thus, the size and shape of the nTiO2 may influence toxicity, being so small, aquatic organisms may take nTiO2 as food and/or within the food. Besides this, interactions of substances at nanosize scale with other chemical/physical factors are greater than those usually established at the micron or higher scales, hence they can cause increased toxicity or other adverse effects in different marine species. Regarding the biological decomposition time, as already stated above, this cannot be due to decomposition because it is not biodegradable, and only can disperse or sediment.
Considering that the nTiO2 are in contact with other particles in the medium that influence aggregation behavior, the concentration of nTiO2 is also a key factor governing the behavior of this material in aqueous media. In particular, in our study, the sedimentation in freshwater was achieved after 10 to 15 h, whereas, the sedimentation in saltwater ranged from 20 to 24 h at the concentration selected.
As TiO2 is a semiconductor material, UV radiation excites its electrons from the valence band to the conduction band, resulting in the generation of an electron-hole (e−/h+) pair. In this situation, the reduction of aqueous dissolved oxygen by e− and oxidation of water by h+ typically leads to the formation of primary ROS such as superoxide and hydroxyl radical, respectively. Once formed, these may lead to the generation of other oxidant species such as singlet oxygen or hydrogen peroxide.
In seawater, mechanisms as mentioned above are likely different, highlighting that high concentrations of halide species (mainly chlorine and bromide anions) would trigger the photocatalytic process to the generation of reactive halogen species [
3,
13].
Previously, phototoxicity bioassays were conducted with
Artemia sp. and demonstrated that this organism is resistant to diverse toxics. Still, in our study, when
Artemia sp. was exposed to nTiO
2 in combination with organic UV filters and high concentrations of nTiO
2, it showed an increased ratio of immobilization. In addition, with high concentrations of nTiO
2 and expanded UV light exposure time [
30].
These outcomes are in agreement with previous studies; Hund-Rinke and Simon [
17], conducted tests involving UV irradiation in a medium containing nTiO
2,
D. magna, and algae, and they concluded that the photocatalytic activity damaged the organism causing a complete immobilization.
According to Matsuo [
31], UVA irradiation at 365 nm for 60 to 100 min to the planktonic species
Artemia salina or
Chatonella Antigua, and 1 mg/L of nTiO
2 caused immobilization in both organisms. Marcone [
32] tested a combination of commercial nTiO
2 (30% rutile and 70% anatase) at 100 mg/L and UVA radiation on
D. magna. The findings suggested that nTiO
2 phototoxicity under UV radiation was the principal cause of the acute toxic effect observed and that the corresponding EC50 value for
D. magna was 5.50 mg/L, similar to the value estimated in the present study. Ma [
33], reported that there was a linear correlation between ROS production and
D. magna immobilization and that ROS formation might be a predictor of the phototoxicity caused by nTiO
2. This ROS production has been probed to cause sublethal oxidative stress in different organisms, such as fish embryos [
34].
Concerning saline organisms, Artemia sp. was subjected to SSR and nTiO2 concentrations and showed an immobilization below 10% in the first bioassay with an EC50 value of 94 mg/L, opposite case with D. magna with the same exposition set up, 10 mg/L of nTiO2 and 16 h UV radiation, and an EC50 value of 6.4 mg/L.
In the second bioassay performed at the same concentrations of nTiO2 but joined with BP3, OC, and EtPABA, three of the most toxic UV organic filters, this organism showed higher immobilization. Our findings suggested that when the UV irradiation exposure and the concentration of nTiO2 increase, even when nTiO2 is combined with the mixture of organic UV filters, the 96 h EC50 was 52 mg/L, indicating low toxicity through the combined effects.
Despite that, concerns have been raised about the occurrence of mixtures of nTiO
2 and organic UV filters in seawater, because of the interaction among these substances, sunlight and halide anions, which may result in the photocatalytic generation of RHS and subsequent halogenation of the organic compounds [
3]. Also, previous studies suggested that the organic UV filters are less photostable (except for oxybenzone), resulting in photolysis and harmful free-oxygen radicals [
35].
In the third set of assays with Artemia sp., the organism exhibited low immobilization when exposed to 24 h continuous radiation. The immobilization ratio was less than 30%. Then, when Artemia sp. continued to be exposed to UV radiation up to 48 h, the immobilization started at low concentration, and 60% immobility was observed. At a higher concentration (100 mg/L), enhanced phototoxicity was registered. This exponential increase in mortality observed may be explained by the extended time at which the organisms were exposed to ROS and RHS.
Aquatic organisms like
D. magna incorporate nTiO
2 via the gut [
36].
Artemia sp. is a filter feeder, and then the nanoparticles may enter their guts through ingestion [
37]. The mortality observed may be due to the uptake of the nTiO
2 in combination with SSR.
The above might be conducted to the organism’s oxidative stress of the organisms besides the ROS and RHS originated during the exposure. According to Ma [
38], the mode of action associated with phototoxicity is SSR, which activates ionic or respiratory stress caused by damage to respiratory and ion-exchanged surfaces by ROS produced when attached or adsorbed nTiO
2.
Therefore, the findings suggested that the increasing concentration of nTiO2 and the long exposure time to solar radiation cause phototoxicity in D. magna and Artemia sp.
6. Conclusions
The present study investigated the phototoxicity of nTiO2 toward two aquatic organisms. D. magna that served as a model organism for a conservative risk assessment of freshwater, and Artemia sp. for saltwater organisms.
D. magna showed as a sensitive organism, and Artemia sp. showed as a resistant organism. Still, the latest showed a different behavior when it was exposed to nTiO2 joined with UV organic filters.
This work describes several bioassays with combinations of experimental conditions, it covers from the lowest concentration of 0.000018 mg/L to a higher concentration of 100 mg/L, and it was demonstrated that UV radiation exposure time of 24 and 48 h, might increase the phototoxicity of the nTiO2.
Also, the results achieved in this study regarding the toxic effects produced by combined stressors exposing on Artemia sp. guarantees subsequent investigations on joint effects when physical and chemical UV filters are combined.
Our findings evidence the increased toxicity of nTiO2 in aquatic environments under solar radiation, and especially when organic sunscreens are simultaneously present. This study also demonstrated the importance of considering not only the concentration of nTiO2 to assess its toxicity but also to consider other factors, i.e., sunlight and co-existing substances to estimate its environmental hazard. Reactive oxygen and halogen species formation in the photoreaction process are involved in the phototoxicity of nTiO2. Thus, significantly different phototoxic effects could be expected in natural waters with large differences in salts content, as is the case between freshwater and seawater.
From the results obtained in the present study, it can be concluded that:
On D. magna:
- (I)
Toxicity on this organism was increased when nTiO2 and irradiation were combined.
- (II)
When the UV irradiation time is extended, the phototoxicity potential of the nTiO2 increases at higher concentrations.
- (III)
A concentration-dependent immobilization process was observed in the simultaneous exposure to 48 h of UV irradiation at 100 mg/L nTiO2.
On Artemia sp.:
- (I)
Exposure to short irradiation time and low nTiO2 showed no phototoxicity.
- (II)
Exposure to irradiation, nTiO2, and a mixture of organic UV filters, a notorious increment of the immobilization rate was observed.
- (III)
A concentration-dependent immobilization process was observed when this organism was exposed to 48 h of UV radiation and 100 mg/L of nTiO2.