Water Depollution and Photo-Detoxification by Means of TiO 2 : Fluoroquinolone Antibiotics as a Case Study

: Photocatalysis by semiconductors is considered one of the most promising advanced oxidation processes (AOPs) and TiO 2 is the most well-studied material for the removal of contaminants from the aquatic system. Over the last 20 years, pharmaceuticals have been the most investigated pollutants. They re-enter the environment almost unmodiﬁed or slightly metabolized, especially in the aquatic environment, since the traditional urban wastewater treatment plants (WWTPs) are not able to abate them. Due to their continuous input, persistence in the environment, and unpleasant e ﬀ ects even at low concentrations, drugs are considered contaminants of emerging concern (ECs). Among these, we chose ﬂuoroquinolone (FQ) antibiotics as an environmental probe for assessing the role of TiO 2 photocatalysis in the degradation of recalcitrant pollutants under environmental conditions and detoxiﬁcation of surface waters and wastewaters. Due to their widespread di ﬀ usion, their presence in the list of the most persistent pollutants, and because they have been deeply investigated and their multiform photochemistry is well-known, they are able to supply rich information, both chemical and toxicological, on all key steps of the oxidative degradation process. The present review article explores, in a non-exhaustive way, the relationship among pollution, toxicity and remediation through titanium dioxide photocatalysis, with particular attention to the toxicological aspect. By using FQs as the probe, in depth indications about the di ﬀ erent phases of the process were obtained, and the results reported in this paper may be useful in the improvement of large-scale applications of this technology, and—through generally valid methods—they could be deployed to other pharmaceuticals and emerging recalcitrant contaminants.


Introduction
The amount of energy consistently reaching Earth in the form of solar light (1366 W m −2 ) [1] largely overcomes any other form of available energy. Almost half of the intensity crosses the atmosphere and reaches the ground.
Plants have evolved with a system, chlorophyll photosynthesis, to extract energy from solar light and convert it into fuel. Man, on the other hand, was not able to directly use this energy (until recent years) and learned to exploit the surplus energy accumulated in plant tissues thriving during the modern era as a result of crude oil exploitation. Uncontrolled utilization of natural and non-renewable resources, on a human time-scale, is no longer sustainable, as suggested by many natural and economic indicators. Although mankind is slowly taking some steps ahead, it still has a lot to learn from plants on how to convert and store solar light effectively and efficiently. On the other hand, we have also connection among pollution, toxicity, and remediation though titanium dioxide photocatalysis. For this purpose, we chose fluoroquinolone antibiotics (FQs) as an environmental probe to demonstrate the efficacy and the efficiency of TiO 2 photocatalysis both in the degradation of recalcitrant and emerging pollutants under real conditions (natural and wastewaters, UV-A and solar light) and its effect on environmental microorganisms.
Specifically, FQs were selected for the following reasons: (1) They absorb strongly in the UV-A region, and they are photochemically reactive [44,47]; (2) they are very useful antibacterial agents and form the last class of antibiotics of large-scale use, particularly in highly developed countries. In the 1980s, molecules of this class were synthesized in Europe and the USA for human use, and about ten years later, as veterinary medicines. They show both a broad activity spectrum against Gram-positive and Gram-negative bacteria, excellent oral absorption, and are also used as a prophylactic in husbandry [48]; (3) their occurrence in the environment has been widely assessed in past decades both in the aquatic and soil environment [18][19][20][21][22][23][24][25][26][27]; (4) the strong stability of the quinolone ring slows down the degradation rate of these biotically resistant molecules. Toxicity is linked to the heteroaromatic ring, and thus is not fully abated in the first steps of the degradation [44][45][46]; (5) the broad knowledge gathered around their photochemical reactivity, photoproducts, and photoreaction mechanism allows a clear separation of the catalyst effect from baseline photoreactivity.

Why We Used TiO 2 and Drugs as the Probe
Water remediation by means of irradiated titanium dioxide suspensions has become by far the most thoroughly investigated topic in the field of photocatalysis and photochemistry in general, with several journals virtually devoted to this topic and an increasing production of publications [2][3][4][5][6][7][8][9].
The sharp increase of papers published in the field is due to the solid evidence of the mechanism and the excellent properties of this material that has a minimal (photo)toxicity, good long-term stability, is low-cost and requires virtually no treatment prior to application. It is true that some increase in efficiency could be obtained either by using a single crystal phase (the commercial material is a mixture of anatase, rutile and brookite) [49][50][51], by controlling the micro-structure or the organization of the semiconductor [52], or through either metal or non-metal ion doping that allows fraction of solar energy absorbed toward the visible to be extend, although this reduces the potentially accessible range of oxidizable molecules [52,53]. The overall efficacy of these changes is still relatively limited and the first experiment carried out with commercial titania powder gives a satisfactory estimate of the final result [49].
The large presence of TiO 2 industrially available as a white pigment for paints, paper, food and other uses offers an inexpensive common basis that facilitates comparisons, often giving the best results directly when using the material in the commercial form (typically Evonik P25).
Even for less experienced researchers, titanium dioxide still remains the first choice and affords a common vocabulary for anybody interested in water depollution.
In principle, the irradiation of the TiO 2 photocatalyst with a light of energy greater than the bandgap of the semiconductor leads to the generation of a couple of positive holes (h + ) in the valence band and free electrons (e − ) in the conduction band.
Photo-induced charge separation on the catalyst surface may overcome electron cb/hole vb recombination (occurring in the ps to ns range) and leads to charge migration within the semiconductor/adsorbed molecule complex. Here, the electron transfer from the organic molecule, occurring at a rate from 10 8 to 10 11 M −1 s −1 , initiates a sequence of reactions that eventually end in complete mineralization, in the so-called process of "cold combustion", which is mechanistically similar to the Fenton reaction. At the same time, photogenerated holes can react with water and generate a Figure 1. Mechanism of TiO2 photocatalysis (ECs-contaminants of emerging concern, TPstransformation products, VB-valence band, CB-conduction band)).
The key steps here are the rates and equilibria of adsorption/desorption of both the parent compound and the reluctant intermediates on the semiconductor surface, and the complex sequence of competing reactions occurring at the semiconductor surface, especially in real matrices. A sequence of intertwined events takes place, each of them undergoing a specific effect, including back electron transfer, and resulting in a largely different efficiency (quantum yield, QY).
A detailed explanation of each of those mechanisms goes beyond the scope of this paper. Nonetheless, the overall process can be generalized in terms of the overall reaction, QY.
The overall photocatalytic QY of the process is influenced by several factors and competing effects occurring under the experimental conditions including, but not limited to, the fraction of light absorbed by the catalyst, the fraction of substrate adsorbed on the catalyst surface, and the rates of competing deactivation (both physical and chemical) reaction pathways.
The single contribution of all these processes to the photocatalytic reaction quantum efficiency often cannot be isolated and independently determined. While a number of overall reaction QYs has been determined for several systems, these are often not far from the QY ≈ 0.1 value estimated by the initial workers, and no largely applicable rationalizations of the changes in QY are available as yet [54][55][56][57].
Dyes have been historically studied because of the easy and sensitive determination of their decomposition, but their use for quantitative measurement of photodegradation appears to be intrinsically a poor choice, especially in environmentally relevant conditions. Indeed, during dye irradiation, many side processes may occur, such as direct light absorption of the dye and sensitization of dissolved oxygen, and this may cause a large error in the evaluation of the process QY [58].
From a practical point of view, drugs are a far better choice in judging the efficiency and efficacy of TiO2 photocatalysis as a means of water depollution and detoxification. In particular, the diversity of available structures has a large impact on their intrinsic photo-reactivity that can be carefully controlled, e.g., many drugs contain a (hetero)-cyclic moiety and thus absorb more light and give primary products that are also photo-reactive, because the aromatic ring is conserved until several steps occur, while the reverse holds for aliphatic drugs. From this perspective, FQs may become a gold standard. As light-driven reactivity is the only open route to FQs removal, this makes this class of antibiotics a perfect model to evaluate the efficacy of TiO2 suspension in real conditions, that is, UV-A or sunlight, and natural and wastewater samples. The extensive knowledge of their physical properties and their peculiar photochemistry help in evaluating the contribution of each underlying reaction mechanism to the overall degradation, thus isolating the purely TiO2-mediated photocatalytic processes from all the other effects. Figure 1. Mechanism of TiO 2 photocatalysis (ECs-contaminants of emerging concern, TPs-transformation products, VB-valence band, CB-conduction band)).

Fluoroquinolone Antibiotics
The key steps here are the rates and equilibria of adsorption/desorption of both the parent compound and the reluctant intermediates on the semiconductor surface, and the complex sequence of competing reactions occurring at the semiconductor surface, especially in real matrices. A sequence of intertwined events takes place, each of them undergoing a specific effect, including back electron transfer, and resulting in a largely different efficiency (quantum yield, QY).
A detailed explanation of each of those mechanisms goes beyond the scope of this paper. Nonetheless, the overall process can be generalized in terms of the overall reaction, QY.
The overall photocatalytic QY of the process is influenced by several factors and competing effects occurring under the experimental conditions including, but not limited to, the fraction of light absorbed by the catalyst, the fraction of substrate adsorbed on the catalyst surface, and the rates of competing deactivation (both physical and chemical) reaction pathways.
The single contribution of all these processes to the photocatalytic reaction quantum efficiency often cannot be isolated and independently determined. While a number of overall reaction QYs has been determined for several systems, these are often not far from the QY ≈ 0.1 value estimated by the initial workers, and no largely applicable rationalizations of the changes in QY are available as yet [54][55][56][57].
Dyes have been historically studied because of the easy and sensitive determination of their decomposition, but their use for quantitative measurement of photodegradation appears to be intrinsically a poor choice, especially in environmentally relevant conditions. Indeed, during dye irradiation, many side processes may occur, such as direct light absorption of the dye and sensitization of dissolved oxygen, and this may cause a large error in the evaluation of the process QY [58].
From a practical point of view, drugs are a far better choice in judging the efficiency and efficacy of TiO 2 photocatalysis as a means of water depollution and detoxification. In particular, the diversity of available structures has a large impact on their intrinsic photo-reactivity that can be carefully controlled, e.g., many drugs contain a (hetero)-cyclic moiety and thus absorb more light and give primary products that are also photo-reactive, because the aromatic ring is conserved until several steps occur, while the reverse holds for aliphatic drugs. From this perspective, FQs may become a gold standard. As light-driven reactivity is the only open route to FQs removal, this makes this class of antibiotics a perfect model to evaluate the efficacy of TiO 2 suspension in real conditions, that is, UV-A or sunlight, and natural and wastewater samples. The extensive knowledge of their physical properties and their peculiar photochemistry help in evaluating the contribution of each underlying reaction mechanism to the overall degradation, thus isolating the purely TiO 2 -mediated photocatalytic processes from all the other effects.

Fluoroquinolone Degradation Kinetics and Phototransformation Products
The oxidation process that occurs during the photocatalytic process involves five steps: (i) Diffusion of the reagent molecules from the bulk to the surface of the catalyst, (ii) adsorption of the reagent molecules on the catalyst surface, (iii) reaction on the surface and TPs formation, (iv) TPs desorption from the catalyst surface, and (v) TPs diffusion in bulk. The most common way to describe this process is the Langmuir-Hinshelwood (L-H) model (Equation (1)): where C is the substrate concentration in the liquid phase after equilibrium, KHL is the LH adsorption coefficient, kr is the reaction rate coefficient, and r is the initial degradation rate. For FQ concentrations ranging from tens of µ g L −1 to tens of mg L −1 , KHL × C is much less than the unity, and the degradation rate can be simplified as follows: All experimental data fit a pseudo-first-order equation:

Fluoroquinolone Degradation Kinetics and Phototransformation Products
The oxidation process that occurs during the photocatalytic process involves five steps: (i) Diffusion of the reagent molecules from the bulk to the surface of the catalyst, (ii) adsorption of the reagent molecules on the catalyst surface, (iii) reaction on the surface and TPs formation, (iv) TPs desorption from the catalyst surface, and (v) TPs diffusion in bulk. The most common way to describe this process is the Langmuir-Hinshelwood (L-H) model (Equation (1)): where C is the substrate concentration in the liquid phase after equilibrium, K HL is the LH adsorption coefficient, k r is the reaction rate coefficient, and r is the initial degradation rate. For FQ concentrations ranging from tens of µg L −1 to tens of mg L −1 , K HL × C is much less than the unity, and the degradation rate can be simplified as follows: All experimental data fit a pseudo-first-order equation: where C 0 is the initial substrate concentration, C is the substrate concentration at time t, and k deg is the kinetic degradation constant. Although many authors calculated the kinetic degradation constant (k deg ) through the common linear correlation between ln [C]/[C 0 ] and the irradiation time, giving undue weight to the first points of the curve, k deg is a more convenient parameter to compare the photocatalytic performances of different systems, since it is independent of concentration. In Table 1, the kinetic degradation constant values are reported.
As shown in Table 1, TiO 2 Degussa P25 is used without modification [49,50]. Hombikat UV100 and PC500 were used by Paul et al. [63] and Venacio et al. [59] for comparison. Differing from P25, they displayed the sole crystallized anatase phase and a higher and microporous specific surface area of 330 and 290 m 2 g −1 , respectively [50,51,58]. Venancio et al. [59] synthesized highly crystalline TiO 2 nanoparticles with a high density through the sol-gel method. Despite the different morpho-structural characteristics, degradation rates were not significantly different from those obtained in the presence of TiO 2 P25.
The influence of different variables in the photo-oxidation process, such as the initial substrate concentration, amount of catalyst, solution pH, oxygen dissolved, temperature, oxidizing species, scavenger effects, and adsorption effects has been investigated by many research groups [59,60,62,65,67,68].
Concentrations of antibiotics in the range 10-50 mg L −1 were appropriately used to facilitate the identification of photodegradation products [60,[62][63][64]67,68,70,71] and the accurate quantification of dissolved organic carbon (DOC) removal [60,64,67,68,71]-a few works were carried out at lower FQ concentrations (100-560 µg L −1 ) [59,61,65,69] to better mimic actual conditions. Ultrapure or deionized water was the most common solvent employed for the photochemical experiments [61][62][63][64]70,71]. It was chosen to avoid any possible interaction by a more complex matrix like surface water and wastewater. It is well known that the matrix constituents of both natural freshwaters and wastewaters may affect the photocatalytic process. Indeed, some inorganic ions and the fraction of natural dissolved organic matter (DOM) can act as photo-sensitizers able to absorb solar light directly [72]. As hinted above, in several cases, transient species are produced in the photosensitized degradation of FQs which exhibit an absorption spectrum similar to that of the starting material, as is normal since it is mostly determined by the heteroaromatic moiety, and may make the process somewhat more complex. It can further be observed that Venancio et al. [59] and Guzman et al. [60] showed that fluoroquinolone degradation occurred slower in natural waters than in ultrapure water; more precisely, the rate of degradation followed the order ultrapure water < simulated water < bottle water < tap water (see Figure 3).  solar light directly [72]. As hinted above, in several cases, transient species are produced in the photosensitized degradation of FQs which exhibit an absorption spectrum similar to that of the starting material, as is normal since it is mostly determined by the heteroaromatic moiety, and may make the process somewhat more complex. It can further be observed that Kumar et al. [70] and Guzman et al. [60] showed that fluoroquinolone degradation occurred slower in natural waters than in ultrapure water; more precisely, the rate of degradation followed the order ultrapure water < simulated water < bottle water < tap water (see Figure 3). Reprinted with permission from [59], copyright 2018, IWA.
Similar, but more marked results were obtained by Hapeshi et al. [67] and Micheal et al. [68] in secondary treated effluent samples taken from an urban WWTP. Around 80% of OFL degraded after 120 minutes of irradiation.
Additionally, the pH of the solution affects the degradation of these antibiotics. The pH is correlated to both the intrinsic properties of the substrate and the surface charge density of the catalyst. It is reported that the adsorption of the organic compound, and thus its degradation, is favored near the zero point charge (zpc) of the catalyst. A medium pH may affect both the position of vb and cb and the band gap energy [65]. At pH 6, zpc of TiO2 P25 is 6, and FQs are mainly in their cationic and zwitterion forms (half way between the pKa of the acidic and the alkaline functional groups, see Figure 4). Adsorption experiments demonstrated that FQs adsorption, ensured by an appropriate stirring time in the dark, onto the surface catalyst was favored at pH values close to neutral. Similar, but more marked results were obtained by Hapeshi et al. [67] and Micheal et al. [68] in secondary treated effluent samples taken from an urban WWTP. Around 80% of OFL degraded after 120 min of irradiation.
Additionally, the pH of the solution affects the degradation of these antibiotics. The pH is correlated to both the intrinsic properties of the substrate and the surface charge density of the catalyst. It is reported that the adsorption of the organic compound, and thus its degradation, is favored near the zero point charge (zpc) of the catalyst. A medium pH may affect both the position of vb and cb and the band gap energy [65]. At pH 6, zpc of TiO 2 P25 is 6, and FQs are mainly in their cationic and zwitterion forms (half way between the pK a of the acidic and the alkaline functional groups, see Figure 4). Adsorption experiments demonstrated that FQs adsorption, ensured by an appropriate stirring time in the dark, onto the surface catalyst was favored at pH values close to neutral.  In neutral or slightly alkaline conditions, like those of natural freshwaters, hydroxyl radicals are more easily generated on the TiO2 catalyst surface due to the oxidation of the adsorbed hydroxyl ions, and therefore the efficiency of the process is enhanced (see Figure 5) [62,67].  In neutral or slightly alkaline conditions, like those of natural freshwaters, hydroxyl radicals are more easily generated on the TiO 2 catalyst surface due to the oxidation of the adsorbed hydroxyl ions, and therefore the efficiency of the process is enhanced (see Figure 5) [62,67].
As expected, the photocatalytic efficiency is affected by the catalyst loading. Indeed, by increasing the catalyst amount, the number of available active sites increases; consequently, the substrate degradation rate rises. On the other hand, concentrations higher than some grams per liter may cause light scattering, poor light penetration or agglomeration phenomena in the suspension, which leads to a sharp drop in the substrate degradation rate [62,65,68].
Other experimental variables, in particular, temperature and oxygen percentage, seem to have minor relevance in the process efficiency. Specifically, Hapeshi et al. [67] observed that the degradation rate was enhanced by bubbling oxygen through the solution, especially in the first steps of the process, while only in the presence of a saturated working solution, fluoroquinolones were quantitatively abated in half the time, as reported by Venancio et al. [59]. In neutral or slightly alkaline conditions, like those of natural freshwaters, hydroxyl radicals are more easily generated on the TiO2 catalyst surface due to the oxidation of the adsorbed hydroxyl ions, and therefore the efficiency of the process is enhanced (see Figure 5) [62,67]. As expected, the photocatalytic efficiency is affected by the catalyst loading. Indeed, by increasing the catalyst amount, the number of available active sites increases; consequently, the substrate degradation rate rises. On the other hand, concentrations higher than some grams per liter may cause light scattering, poor light penetration or agglomeration phenomena in the suspension, which leads to a sharp drop in the substrate degradation rate [62,65,68].
Other experimental variables, in particular, temperature and oxygen percentage, seem to have minor relevance in the process efficiency. Specifically, Hapeshi et al. [67] observed that the degradation rate was enhanced by bubbling oxygen through the solution, especially in the first steps of the process, while only in the presence of a saturated working solution, fluoroquinolones were quantitatively abated in half the time, as reported by Venancio et al. [59].
Micheal et al. [68] demonstrated that the effect of temperature had no significant impact on the conversion rate.
On the other hand, the addition of an oxidizing reagent, such as hydrogen peroxide, promotes both the oxidation process and total organic carbon (TOC) removal [59,62,65,67,71]. A slight increase in the degradation rate was observed, increasing H2O2 from 0.14 to 5.5 mM (see Table 1).
On the contrary, a decrease in the degradation rate was found by Biancullo et al. in the presence of a radical scavenger, such as MeOH (see Table 1) [65].
A comparison of the rates of degradation of CIP using different irradiation protocols revealed that UV-A/TiO2 photocatalysis was more efficient than Vis/TiO2 one, as shown by Paul et al. [63].
A higher kinetic degradation constant value, and consequently, a higher percentage of dissolved organic carbon, was obtained by using UV-A sonophotocatalytic treatment. Ultrasonic radiation Micheal et al. [68] demonstrated that the effect of temperature had no significant impact on the conversion rate.
On the other hand, the addition of an oxidizing reagent, such as hydrogen peroxide, promotes both the oxidation process and total organic carbon (TOC) removal [62,67,68]. A slight increase in the degradation rate was observed, increasing H 2 O 2 from 0.14 to 5.5 mM (see Table 1).
On the contrary, a decrease in the degradation rate was found by Biancullo et al. in the presence of a radical scavenger, such as MeOH (see Table 1) [65].
A comparison of the rates of degradation of CIP using different irradiation protocols revealed that UV-A/TiO 2 photocatalysis was more efficient than Vis/TiO 2 one, as shown by Paul et al. [63].
A higher kinetic degradation constant value, and consequently, a higher percentage of dissolved organic carbon, was obtained by using UV-A sonophotocatalytic treatment. Ultrasonic radiation applied by Hapeshi et al. [67] contributed to promoting the formation of reactive radicals, favored the substrate mass transfer from the bulk to the catalyst surface, and helped to avoid particle aggregation.
Biancullo et al. [65] obtained the highest k deg value by using a UV-A irradiation LEDs system that was more efficient than the traditional lamps.
The identification and quantification of transformation products arising from photo-reactive molecules is a difficult task because no analytical standards are available for their identification and quantification; moreover, many different TPs may occur depending on the experimental and analytical setup [73]. Despite this limitation, TPs' evolution profiles are usually monitored, and chemical structures are proposed with an acceptable degree of certainty.
As for the photocatalytic degradation of FQs, many TPs were already present in the early steps of the process, with a lifetime usually in the same order as that of the starting molecule. On the contrary, the presence of secondary photoproducts was often confirmed by TOC measurements, which still indicated the presence of an organic load after the substrate degradation was complete en route to mineralization (see Figure 6) [60,64,67,68,71].
Generally, and in all the considered research papers, the chemical structures of TPs were based on high-resolution mass determination, and mechanistic pathways were quite accurately suggested. Unlike direct photolysis, in the presence of a photocatalyst, the oxidative degradation of the electron-rich amine side-chain results in the main chemical path followed by hydroxylation and decarboxylation, while photoproducts coming from direct photolysis, such as reductive dehalogenation and fluorine substitution, are not predominant as reported in most of the considered papers (see Scheme 1 and Table 1) [45].
analytical setup [73]. Despite this limitation, TPs' evolution profiles are usually monitored, and chemical structures are proposed with an acceptable degree of certainty.
As for the photocatalytic degradation of FQs, many TPs were already present in the early steps of the process, with a lifetime usually in the same order as that of the starting molecule. On the contrary, the presence of secondary photoproducts was often confirmed by TOC measurements, which still indicated the presence of an organic load after the substrate degradation was complete en route to mineralization (see Figure 6) [60,64,67,68,71]. Generally, and in all the considered research papers, the chemical structures of TPs were based on high-resolution mass determination, and mechanistic pathways were quite accurately suggested. Unlike direct photolysis, in the presence of a photocatalyst, the oxidative degradation of the electronrich amine side-chain results in the main chemical path followed by hydroxylation and decarboxylation, while photoproducts coming from direct photolysis, such as reductive dehalogenation and fluorine substitution, are not predominant as reported in most of the considered papers (see Scheme 1 and Table 1) [45].
At the experimentally reported TiO2 concentrations, most of the light is absorbed by the titania particles, which then interact through hydrogen or electron transfer with the adsorbed drug [45,74,75]. Furthermore, FQ activation and degradation can also be initiated by energy transfer   At the experimentally reported TiO 2 concentrations, most of the light is absorbed by the titania particles, which then interact through hydrogen or electron transfer with the adsorbed drug [45,74,75]. Furthermore, FQ activation and degradation can also be initiated by energy transfer between photoactivated titania nanoparticles and FQs, producing a triplet of the latter, as reported in our previous works on Ofloxacin [76]. This mechanism accounts for the identification of low quantities of secondary products from direct photolysis.
Direct photolysis initiated photodegradation suffers from the limited part of the solar spectrum the FQs can absorb (usually below 380 nm for most FQs), which does not cover the visible part of the spectrum, and from the competitive light absorption of many other environmentally present organic compounds. Furthermore, the main photo-reaction paths for FQs are accessible only through their long-living triplet excited state; this transient must be populated through Inter System Crossing (ISC) from the first excited singlet and, once formed, may suffer from different deactivation pathways which can compete with photoreaction (i.e., electron transfer and energy transfer) especially under real conditions where inorganic ions and organic compounds may easily foster these processes. When direct photolysis occurs, products from reductive dehalogenation and fluorine substitution dominate in the 6-FQs family, while the presence of a second fluorine atom at position 8, in addition, to increasing the photoreaction quantum yield, shifts the reactivity toward F elimination from C8. Unlike photolysis, during photocatalysis at the commonly employed concentrations, most of the light is absorbed by the semiconductor and not by the molecule used as the probe [74,75]. Furthermore, the TiO 2 UV-Vis absorption spectrum expands toward the visible region of light (400-410 nm, 3.0-3.2 eV), depending on the crystalline structure [77]. This allows for a better exploitation of sunlight radiation. In this case, after light absorption and electron-hole pair generation in the semiconductor, the FQ molecule adsorbed onto the catalyst surface reacts mostly through either direct or OH radical-mediated hydrogen and electron transfer [45]. This privileged reaction path in the presence of titanium dioxide photocatalyst massively increases the number of photoproducts originating from the oxidative degradation of the electron-rich FQs side-chains (Scheme 1 and Table 1). It ultimately initiates a cascade of reactions, eventually leading to complete mineralization and pollutant removal, with only water and carbon dioxide being released as by-products.

Antibacterial and Ecotoxicological Tests
As is apparent, TiO 2 is a strong photo-oxidant and has a bactericidal action towards a broad spectrum of harmful microorganisms [14,78,79]. For this reason, microbiological and eco-toxicological tests performed on irradiated samples are useful tools to evaluate the efficiency and the efficacy of the photocatalytic process, both in terms of degradation (decomposition degree of the target molecules) and detoxification (inactivation of the active principles, evaluation of acute and chronic effects against microorganisms). Nevertheless, testing the residual toxicity of toxic substances, such as pharmaceuticals, is a critical task, as sometimes the degradation TPs are more toxic than the parent compound, and at the same time it is impossible to isolate TPs. Due to the different experimental set ups, a significant variability among the obtained data was observed, although each test was performed following the standard guidelines [14,71].
In general, the experimental measurements allowed us to calculate the growth inhibition (I%) according to the following equation: where S control is the signal measured in the control sample, and S sample is the signal measured in the irradiated sample.
A dose-response curve may be obtained by plotting the I% calculated for each sample dilution against the log of the corresponding sample dilution. The log of the effective dose that causes 50% of the growth inhibition is reported as EC50.
An EC50 value against P. subcapitata was reported by Van Doorslaer et al. [71], who declared to have obtained the lowest value among those reported in the literature. It is apparent that by increasing the photocatalytic treatment, the inhibition decreases significantly, as shown by Paul et al. [63] (see Figure 7) and Venancio et al. [59], despite the different experimental conditions.
A dose-response curve may be obtained by plotting the I% calculated for each sample dilution against the log of the corresponding sample dilution. The log of the effective dose that causes 50% of the growth inhibition is reported as EC50.
An EC50 value against P. subcapitata was reported by Van Doorslaer et al. [71], who declared to have obtained the lowest value among those reported in the literature. It is apparent that by increasing the photocatalytic treatment, the inhibition decreases significantly, as shown by Paul et al. [63] (see Figure 7) and Venancio et al. [71], despite the different experimental conditions. Vis-TiO2 photocatalysis, and (c) UVA-TiO2 photocatalysis in solutions initially dosed with 100 μM ciprofloxacin at pH 6, 25 °C, and 0.5 g/L TiO2 (for photocatalysis experiments). The averages of triplicate experimental measurements are shown with corresponding 95% confidence intervals. The independent variable "dilution" is equal to 1/2n, where "2" is the serial dilution factor used in preparing dose-response series (i.e., for two-fold, or 1:1 dilution), and "n" the number of times a given sample has been serially diluted relative to the corresponding parent sample (i.e., 1/20 = 1 corresponds to the undiluted sample). Reprinted with permission from [63], copyright 2010, Elsevier.
Antibacterial and eco-toxicological tests used to evaluate changes in the residual antibacterial activity and the toxicity of FQs and their photoproducts are shown in Table 1.
Antibacterial and eco-toxicological tests used to evaluate changes in the residual antibacterial activity and the toxicity of FQs and their photoproducts are shown in Table 1.
Van Dooslar et al. chose P. supcapitata as a model organism to evaluate the potential adverse effects occurring during MOX degradation [71]. They observed a significant increase of EC50 in the first hour of irradiation when the antibiotic was still present in the solution, while for longer irradiation times (90-150 min, MOX < LOD), the growth inhibition decreased from 72% to 14%. The residual toxicity and the poor carbon mineralization compared with the parent compound conversion confirmed the presence of TPs. Their lower toxicity may be ascribable either to a decrease of biological activity or to a minor permeation through the cell membrane due to their larger hydrophilicity compared to MOX.
A UV-A sonophotocatalytic treatment of OFL aqueous solutions against D. magna was carried out by Hapeshi et al. [67]. OFL was quickly consumed after 30 min of treatment leading to the formation of 20 TPs, while D. magna immobilization increased from 20% to 55% after 24 h and 48 h of exposure, respectively. A decrease in daphnid immobilization up to 5% was observed after 240 min of treatment, when TPs were removed.
Similar, but less marked results were obtained during the UV-A photocatalytic treatment of OFL, carried out under both the same experimental conditions [67] and in other work [68] in the presence of 3 g L −1 TiO 2 . In both cases, incomplete mineralization (around 10%) was observed after the antibiotic degradation confirmed the presence of toxic intermediates and daphnid immobilization up to 25% at a long-term exposure. The long-term toxicity was due to the formation of photoproducts that maintain the core quinolone structure.
Calza et al. [64] reported a reduction in the natural emission of the luminescent bacteria V. fisheri within the first 10 min of the OFL photolytic treatment, corresponding to a 55% inhibition after only 15 min of incubation. The simultaneous disappearance of the parent compound and the occurrence of TPs indicated that the toxicity was strictly correlated to TPs, especially when they retain the quinolone core structure. From 15 to 120 min of irradiation, the percentage inhibition decreased and TOC was almost completely abated (85%). An inhibition percentage below 1% and complete mineralization of the organic carbon was obtained after four hours of treatment (see Figure 8).
activity or to a minor permeation through the cell membrane due to their larger hydrophilicity compared to MOX.
A UV-A sonophotocatalytic treatment of OFL aqueous solutions against D. magna was carried out by Hapeshi et al. [67]. OFL was quickly consumed after 30 minutes of treatment leading to the formation of 20 TPs, while D. magna immobilization increased from 20% to 55% after 24h and 48h of exposure, respectively. A decrease in daphnid immobilization up to 5% was observed after 240 min of treatment, when TPs were removed.
Similar, but less marked results were obtained during the UV-A photocatalytic treatment of OFL, carried out under both the same experimental conditions [67] and in other work [68] in the presence of 3 g L −1 TiO2. In both cases, incomplete mineralization (around 10%) was observed after the antibiotic degradation confirmed the presence of toxic intermediates and daphnid immobilization up to 25% at a long-term exposure. The long-term toxicity was due to the formation of photoproducts that maintain the core quinolone structure.
Calza et al. [64] reported a reduction in the natural emission of the luminescent bacteria V. fisheri within the first 10 minutes of the OFL photolytic treatment, corresponding to a 55% inhibition after only 15 minutes of incubation. The simultaneous disappearance of the parent compound and the occurrence of TPs indicated that the toxicity was strictly correlated to TPs, especially when they retain the quinolone core structure. From 15 to 120 minutes of irradiation, the percentage inhibition decreased and TOC was almost completely abated (85%). An inhibition percentage below 1% and complete mineralization of the organic carbon was obtained after four hours of treatment (see Figure  8).
The V. fisheri bioassay was also adopted to investigate the eco-toxicological effects of CIP photodegradation [61,64]. For Calza et al. [64], CIP aqueous solutions tested at different irradiation times (2-240 minutes) were non-toxic, indicating that CIP degradation proceeded through the formation of non-toxic TPs, even if more than four hours of irradiation were necessary to obtain a 100% TOC abatement (see Figure 8). In contrast, higher toxicity (70%) against V. fisheri in more diluted CIP solutions and for long irradiation time (45 min) was observed by Silva et al. [61], who did not exclude that irradiation in the presence of titanium dioxide may lead to toxic effects.
In good agreement with Calza's results, Paul et al. [63] demonstrated that for each mole of CIP degraded, the antimicrobial load (E. coli) in the irradiated solution decreased by a "mole", indicating The V. fisheri bioassay was also adopted to investigate the eco-toxicological effects of CIP photodegradation [61,64]. For Calza et al. [64], CIP aqueous solutions tested at different irradiation times (2-240 min) were non-toxic, indicating that CIP degradation proceeded through the formation of non-toxic TPs, even if more than four hours of irradiation were necessary to obtain a 100% TOC abatement (see Figure 8).
In contrast, higher toxicity (70%) against V. fisheri in more diluted CIP solutions and for long irradiation time (45 min) was observed by Silva et al. [61], who did not exclude that irradiation in the presence of titanium dioxide may lead to toxic effects.
In good agreement with Calza's results, Paul et al. [63] demonstrated that for each mole of CIP degraded, the antimicrobial load (E. coli) in the irradiated solution decreased by a "mole", indicating that TPs retained a negligible antibacterial activity compared to the parent compound. The stoichiometric release of ammonium and fluoride ions confirmed quantitative CIP abatement, which was achieved faster under UV-A TiO 2 than Vis-TiO 2 .
Comparable findings were reported by Guzman et al. [60] both in distilled and mineral waters. CIP-irradiated samples (95% degradation, mineralization not exceeding 35%) were less harmful than non-irradiated samples, even if Gram-positive bacteria (S. aureus) seemed more vulnerable than the Gram-negative bacteria (E. coli) to the main TPs (by about two-fold), which conserved the quinolone ring but not the amino-side chain.
Only three papers among those examined investigated the biological activity of the sole parent compound [59,62,70].
Venancio et al. [59] assessed the residual CIP, LOM, and OFL antibacterial activity against Gram-positive (B. subtilis) and Gram-negative (E. coli) strains during TiO 2 P25 and PC500 photocatalytic treatment. TiO 2 P25 removed almost the total antibacterial activity in a shorter reaction time (120 min of irradiation) compared to PC500. Similar results were obtained by Li et al. [62]. An inhibition of 50% of the initial E. coli activity was reached after 120 min of irradiation with concentrated solutions of CIP, ENR, NOR, OFL. Although mineralization required a longer irradiation time than FQs degradation, biological activity was removed within 180 min.
A total of 90 min of treatment on the LEV solution in the presence of a TiO 2 homemade catalyst was enough to inhibit E. coli resistance completely [70].
Only two studies analyzed the photocatalytic degradation of a mixture of pharmaceuticals in effluents from urban WWTPs [65,69]. Today, urban WWTPs are considered a hot-spot for antibiotic-resistant bacteria proliferation, and clear data on the adverse toxic effects due to pharmaceuticals at actual concentrations on simple living organisms are still lacking.
Preliminary results were proposed by Andreozzi et al. [69]. They carried out toxicity tests exposing blue-green algae and a rotifer to an irradiated moderately hard synthetic aqueous sample containing OFL and other five pharmaceuticals at a concentration of hundredths of nanograms per liter.
The solutions were irradiated for 48h in the presence of either suspended or immobilized TiO 2 . A slight reduction (9%) in the initial bioactivity was observed in the catalyst suspension, while supported TiO 2 nanoparticles on a membrane were less efficient than suspended nanoparticles. Based on the poor results obtained, the authors suppose that the presence of toxic TPs formed during the photocatalytic treatment.
Additional information was recently reported in a novel disinfection study by means of UV-A LEDs system applied to different WWTP samples collected on different days before and after spiking with a few hundredths of nanograms per liter of a mixture of antibiotics [65]. Interestingly, the count of various bacterial groups (heterotrophs, E. coli, and Enterococcaceae) was carried out both after the photocatalytic treatment and after three days of storage in the dark at room temperature. Although one-hour UV-A LED-irradiation was enough to inhibit the bacterial activity (about two log-units), a significant regrowth was observed after three days of storage. Specifically, the antibiotic resistance after treatment was similar to that of non-treated WWTP samples for heterotrophs and E coli and lower for Enterococcaceae (see Figure 9). This phenomenon, not yet completely investigated, may be attributed to organic matter produced during the oxidative process. As is evident, actual matrices can play an important role not only in the photodegradation of recalcitrant molecules, but also in the photo-detoxification process.
Lastly, Vasquez et al. [66] described a 28 day biodegradability test where the microbiological conditions of the aqueous environment were simulated following the OECD guidelines. They evaluated the potential biodegradability of OFL and its transformation products formed during both the photocatalytic treatment and biotransformation processes. Although OFL was degraded quickly, mineralization remained low (6%), and the biodegradability value was negligible (around zero). These results indicated that primary TPs were not readily biodegradable, especially when fluorine was still present on the heteroaromatic ring. Figure 9. Total (colored) and antibiotic resistant (grey) bacteria inactivation after 1 h photolysis/photocatalysis evaluated immediately (filled bars) and after three days of storage in the dark at room temperature (striped bars). The letters a, b, c, d, and e indicate significantly (p < 0.05) different groups among the tested treatment conditions. The letters in black on the top of bars refer to total bacteria. The letters in white refer to the antibiotic resistant counterparts. The letters on the bottom of the graph refer to the percentage of resistant bacteria with respect to the total bacteria. Reprinted with permission from [65], copyright 2019, Elsevier.
Lastly, Vasquez et al. [66] described a 28 day biodegradability test where the microbiological conditions of the aqueous environment were simulated following the OECD guidelines. They evaluated the potential biodegradability of OFL and its transformation products formed during both the photocatalytic treatment and biotransformation processes. Although OFL was degraded quickly, mineralization remained low (6%), and the biodegradability value was negligible (around zero). These results indicated that primary TPs were not readily biodegradable, especially when fluorine was still present on the heteroaromatic ring.

Conclusions on Benefits and Drawbacks
The widespread diffusion of drugs and pharmaceutical active compounds in the environment, especially in the aquatic compartment, is a matter of serious concern, since these are not abated by traditional urban WWTPs.
This review suggested, through the exploitation of results obtained with an appropriate model molecule (FQ), that TiO2 photocatalysis may be considered as an efficient and convenient advanced oxidation process for the removal of pharmaceuticals from contaminated waters. Specifically, it may be considered one of the best advanced oxidation processes, being a safe and effective mineralization of the pollutants that requires no addition of chemicals, except the semiconductor, and may take place under natural sunlight. As opposed to simple photolysis, TiO2 photocatalytic treatment is efficient in removing the harmful effects due to the presence of drug residues and TPs in the aquatic environment.
The detailed knowledge about the photo-reactivity of FQs and toxicity of their photoproducts offers a useful model both for predicting the effectiveness of the photocatalytic treatment against other persistent compounds and for rationalizing the behavior of new composite materials. Nevertheless, in our opinion, many key aspects still require some attention. . Total (colored) and antibiotic resistant (grey) bacteria inactivation after 1 h photolysis/ photocatalysis evaluated immediately (filled bars) and after three days of storage in the dark at room temperature (striped bars). The letters a, b, c, d, and e indicate significantly (p < 0.05) different groups among the tested treatment conditions. The letters in black on the top of bars refer to total bacteria. The letters in white refer to the antibiotic resistant counterparts. The letters on the bottom of the graph refer to the percentage of resistant bacteria with respect to the total bacteria. Reprinted with permission from [65], copyright 2019, Elsevier.

Conclusions on Benefits and Drawbacks
The widespread diffusion of drugs and pharmaceutical active compounds in the environment, especially in the aquatic compartment, is a matter of serious concern, since these are not abated by traditional urban WWTPs.
This review suggested, through the exploitation of results obtained with an appropriate model molecule (FQ), that TiO 2 photocatalysis may be considered as an efficient and convenient advanced oxidation process for the removal of pharmaceuticals from contaminated waters. Specifically, it may be considered one of the best advanced oxidation processes, being a safe and effective mineralization of the pollutants that requires no addition of chemicals, except the semiconductor, and may take place under natural sunlight. As opposed to simple photolysis, TiO 2 photocatalytic treatment is efficient in removing the harmful effects due to the presence of drug residues and TPs in the aquatic environment.
The detailed knowledge about the photo-reactivity of FQs and toxicity of their photoproducts offers a useful model both for predicting the effectiveness of the photocatalytic treatment against other persistent compounds and for rationalizing the behavior of new composite materials. Nevertheless, in our opinion, many key aspects still require some attention.
Although laboratory experiments allowed for an almost complete mineralization of pharmaceuticals and a complete reduction of the residual antibacterial activity, an absolute validity and a direct cross-reading for other persistent contaminants must be evaluated, especially in terms of their ecotoxicological effects. Furthermore, a full validation of this method to large-scale application and exhaustive case models are still missing.
The generated photoproducts, easy to recognize at the laboratory scale due to their higher concentrations and controlled experimental conditions, are difficult to determine in the presence of a matrix of environmental constituents, as well their additive, synergistic, or antagonist effects in the presence of a mixture of contaminants. This point must be carefully taken into consideration during the identification of proper assays for the determination of the efficacy of TiO 2 AOP in real cases.
Problems related to the losses of catalyst in the environment, and its post-treatment separation and recovery cannot be ignored and must be accounted for. Nonetheless, the versatility of TiO 2 and deep knowledge of its properties, supported by many years of scientific studies, open the door to further technological improvements, such as immobilization and magnetic recovery, which certainly will take this powerful AOP towards widespread application in the near future.