Abstract
In this work, iron oxide nanoparticles (Fe3O4 NPs) were modified by chitosan (CS). Fe3O4 NPs were synthesized by co-precipitation method and their antimicrobial potential and photo-catalytic degradation of Chloramine T (CT) were investigated. The free Fe3O4 NPs and chitosan-coated Fe3O4 NPs (CS-Fe3O4 NPs) were characterized by XRD, FTIR, SEM, and HRTEM. Fe3O4 NPs have spherical shape and their diameter varied from 18.0 nm to 25.0 nm with average particle size at 21.0 nm. Antimicrobial activity was tested towards some pathogenic bacteria and Candida cells as zone of inhibition (ZOI) and minimum inhibitory concentration (MIC). UV-assisted photocatalytic degradation of CT was investigated. Various parameters affecting the photocatalytic efficiency such as (pH on CT removal, CT initial concentration, and adsorbent dose) were studied. Antimicrobial results showed that CS-Fe3O4 NPs possesses a maximum potential against Escherichia coli, Bacillus subtilis and Candida albicans, by 18.0, 17.0, 14.2 mm ZOI, respectively. Results obtained from the photocatalytic activity indicated that CS-Fe3O4 NPs (2.0 gm/l) possessed a promising removal potential, achieving 86.0% removal of CT in the neutral solution (pH = 7.0). The synthesized CS-Fe3O4 NPs are effective for the removal of CT and potent disinfectant agent for pathogenic microbes with possible application in the wastewater treatment.
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Introduction
Nanotechnology has emerged as one of the most versatile fields in recent years [1, 2]. Nanoparticles (NPs) are drawing increasing attention due to their distinctive characteristics and minimal harmful effects [3, 4]. Magnetic NPs are becoming popular in bioengineering and biomedical applications [5, 6], due to their capability to act at the cellular and molecular level when exerted to in vitro and in vivo applications [7, 8]. Among NPs, iron oxide (Fe3O4) NPs are popular due to features such as superparamagnetic, biocompatibility, crystalline structure, non-toxicity, monodispersity, water soluble, and cost-effective in the synthetic method [9, 10].
The crystalline morphology of Fe3O4 NPs consists of a high number of edges, corners and potentially-reactive sites which create an interest as potential antibacterial agents [11]. NPs with the size of less than 100 nm have consistent physical and chemical properties [12,13,14]. To make them suitable for bioengineering and biomedical applications they need to be coated to assure their without toxicity and stability in the biological medium [15, 16]. The surface coating agents may be enzymes, antibodies, proteins, drugs and polyelectrolytes to achieve better interactive properties on the surface of the synthesized NP [17].
The preferred process for the synthesis of Fe3O4 NPs is co-precipitation, because of its simplicity, and that it is carried out under the mild condition without using any hazardous solvents. It has the potential for large-scale production, is cost effective and water soluble, all the necessary requirements for biomedical applications [18]. The crucial challenge in synthesis is to attain the optimum size and shape of the synthesized NPs, which is achieved by controlling pH, temperature, the nature of the salts, ionic strength and the insertion of the surface coating agents [19, 20]. Nanoparticles usually aggregate due to high surface energy and magnetisation [21, 22]. To avoid such aggregation, they are coated with a surface coating agent [23].
Chitosan, a biopolymer which is obtained from deacetylation of chitin, is a biocompatible, biodegradable, linear polysaccharide and consisting of three types of functional groups (amino, and primary and secondary hydroxyl groups) [24, 25]. These serve as an anchor for combining therapeutics, imaging agents and targeting ligands [18, 26]. Chitosan has antimicrobial activity against various microbes, and a negligible toxicity towards human cells [27].
Using standard microbiological methods [28, 29], we tested the antimicrobial properties of synthesised NPs on Escherichia coli, Bacillus subtilis, Pseudomonas aeruginosa, Staphylococcus aureus and Candida albicans; which responsible for infection Candidiasis, and forms a biofilm on the surface of the implantable biomedical devices [30]. E. coli is responsible for 80% of urinary tract infections (UTIs) [31,32,33]. Our objective was to synthesise chitosan-coated Fe3O4 NPs and evaluate their antimicrobial activity, and finally to explore the photocatalytic degradation of chloramine T (CT) from aqueous media. CT is an organic sodium salt derivative of toluene-4-sulfonamide with a chloro substituent in place of amino hydrogen. It must be noted that CT possesses chronic symptoms such as allergy, asthma and/or breathing problems if inhaled, additionally, it may cause critical skin burns and eye damage in low doses [34, 35]. Roorda et al. [36], reported the first case of an anaphylactic reaction caused by immediate-type hypersensitivity to CT. On review of the literature, we found several case reports describing urticaria, rhinitis and asthmatic bronchial obstruction caused by CT after skin contact or airborne exposure [37, 38].
Experimental Section
Chemicals and Reagents
Iron (III) chloride hexahydrate (FeCl3. 6H2O), iron (II) chloride tetrahydrate (FeCl2. 4H2O), sodium hydroxide (Na OH), chitosan (C6H11NO4) n with deacetylation degree of 86 %, MW = 60 kDa, glacial acetic acid, cetyl trimethyl-ammonium bromide (CTAB), and chloramine T (CT) were purchased from E-Merck Products. All other reagents were analytical grade and directly-used without any purification.
Synthesis of Magnetite Nanoparticles (Fe3O4 Nps) by Co-precipitation Method
Aqueous solutions of Fe2+ and Fe3+ in their molar ratio (1: 2) are prepared in deionized water. Solutions are mixed in a separate flask and kept on ultrasonic stirrer for 10–15 min at room temperature to get homogenized solution. After that aqueous solution of Na OH (1 M) is added to the mixture of salt solutions drop wise at a fixed rate and elevated temperature (90 °C) on ultrasonic stirrer.
Co-precipitation occurs in alkaline medium between pH 8–14. Mixing and stirring continues till all salts are precipitated in black colour (formation of Fe3O4 NPs). Reaction is completed in two hours and further half an hour is required for aging. The black precipitate of magnetite NPs is separated by using external magnetic field and washed three times with deionized water till pH is near neutral (6.5). Finally, the magnetic Fe3O4 NPs were obtained after drying in a vacuum oven. The chemical reaction during the co-precipitation of ferrous and ferric salts occurs as follows (Eq. 1):
In the present study instead of maintaining inert atmosphere to check the oxidation of ferrous ions (Fe2+), co-precipitation was allowed at high temperature (80–90 °C).
Synthesis of Chitosan-coated Magnetite Nanoparticles (CS-Fe3O4 NPs)
The surface of magnetic Fe3O4 NPs was coated with a solution of CS for the purpose of obtaining modified Fe3O4 NPs. In a typical experiment, 0.25 g of magnetic Fe3O4 NPs was dispersed in a surfactant containing CTAB (2 g of CTAB dissolved in 400 ml of de-ionized water) (solution C) [39]. Then, 100 ml chitosan solution (0.02 g CS powders dissolved in 100 ml of 1% (w/v) acetic acid solution) was slowly-dropped into solution C. The mixture was continuously-stirred with a rotational speed of 1000 rpm for 1 hour at room temperature [39]. Then, CS coated by Fe3O4 NPs was magnetically-separated from solution by a magnet bar and thoroughly-washed several times with ethanol and deionized water. Finally, the obtained nanocomposites were dried overnight at 60 °C [39].
Characterization of Fe3O4 NPs and CS-Fe3O4 NPs
Powder X-ray diffraction (XRD) patterns were used to determine the crystal structures of the samples over a range of 20°–70°, using an XRD-6000 diffractometer (Shimadzu, Tokyo, Japan) with Cu Kα radiation (λ 1.5406 Å) at 30 kV and 30 mA. Fourier transform infrared (FTIR) spectra of the materials were recorded over a range of 400–4,000 cm−1, using a Nexus, Smart Orbit spectrometer (Thermo Fisher Scientific, Waltham, MA, USA) and the KBr disk method. The surface structure and homogeneity of the synthesized Fe3O4 NPs and CS-Fe3O4 NPs were characterized by scanning electron microscopy (SEM) ZEISS. The images of HRTEM were taken by a JEM-1010 (Jeol, Japan) operated at an accelerating voltage of 200 kV for determining the shape and size of the synthesized NPs.
Photocatalytic Degradation of Chloramine T (CT)
The photocatalytic degradation studies of the synthesized pure Fe3O4 NPs and chitosan functionalized Fe3O4 NPs (CS-Fe3O4 NPs) for removal of chloramine T (CT) were performed with batch equilibrium method [40]. A stock solution (100 mg/l) of CT was prepared by dissolving 0.1 g of CT powder in de-ionized water, and experimental solutions of desired CT concentrations were obtained by successive dilutions of the stock solution with de-ionized water.
(10 mg) of the prepared CS-Fe3O4 nanocomposite were added to (50 ml) of an aqueous solution of CT with initial concentration (Co = 20 mg/L), under constant stirring at ambient temperature (24.0 ± 2 °C) for 30 min in dark, until adsorption–desorption equilibrium is attained between CT and the prepared photocatalyst (nanocomposite).
The used UV reactor was cylindrical shape having dimensions of 27 cm length, and 2.5 cm diameter and made up of stainless steel. The photo-reactor filled with 50 ml of contaminated solutions. The source of UV light is a 10 W high pressure mercury lamp (mean wavelength = 254 nm). At constant time intervals of irradiation, a syringe equipped with a filter (2.5 μm pore size) was used to draw out a sample of CT (3 ml).
The sample was then centrifuged for 10 min at 5000 rpm, to separate the photocatalyst. The degradation rate of CT was calculated by determining the variation in CT concentration verses irradiation time, by a UV–Vis. spectrophotometer (Agilent Technologies Cary 60 UV–Vis), at λmax = 225 nm. De-ionized water was used as a reference [40].
Antimicrobial Activity of Fe3O4 NPs and CS-Fe3O4 NPs
The synthesized chitosan coated magnetic Fe3O4 NPs (CS-Fe3O4 NPs; 10.0 µg/ml) were tested for their antimicrobial performance after conducting the agar-disc distribution process [41,42,43,44]. All samples were examined upon several isolates of pathogenic bacteria-causing urinary tract infection (UTI) which received from the culture collections in Drug Microbiology Lab., Drug Radiation Research Dep., NCRRT, Cairo, Egypt. Bacterial strains were E. coli, S. aureus, B. subtilis, P. aeroginosa and Candida albicans. The bacterial inoculums were fixed at 0.5 McFarland (1–3) × 108 CFU/ml, at a fixed 600 nm UV–Vis. spectrophotometer [45, 46]. The growth inhibition of all the investigated bacterial and yeast strains was estimated by the zone of inhibition (ZOI) after 24 hours incubation [42, 46]. Standard antibiotic discs Gentamycin (CN) at conc. 10 μg/ml and Nystatin (NS) at concentration 100 μg/ml with 6.0 mm diameter were chosen to determine the performance of the considered magnetic Fe3O4 NPs and CS-Fe3O4 NPs.
The serial dilutions method of Luria–Bertani (LB) medium was applied to determine the minimum inhibitory concentrations (MIC) of the tested CS-Fe3O4 NPs and Fe3O4 NPs [43, 47]. For these determinations, a negative control such as the medium broth, positive control such as the examined pathogenic microbes and the used medium broth and CS-Fe3O4 NPs and Fe3O4 NPs (beginning with concentration = 20.0 µg/ml) were applied. MIC was determined next 24 hours of incubation at 36.0 ± 1.0 °C [48, 49].
The inoculums were fixed as mentioned-before in the first antimicrobial screening [45, 49]. MIC was defined by using the ELISA plate method after setting the fixed wavelength at 600 nm [48, 50]. The MIC was described as the lowest concentration of CS-Fe3O4 NPs and Fe3O4 NPs that inhibits 99.0% of the growth of the tested bacteria and yeast cells.
Statistical Analysis
The mathematical analysis of the effects was conducted by applying the ONE WAY ANOVA (at P < 0.05), the least significant differences (LSD), and Duncan's multiple systems [51]. The effects and data were examined and decided through SPSS software (version 15).
Results and Discussion
Characterization of the Prepared Fe3O4 NPs and CS-Fe3O4 NPs
X-Ray Diffraction
Figure 1 shows the results of x-ray diffraction (XRD) analysis for magnetic Fe3O4 NPs and CS-Fe3O4 NPs synthesized by co-precipitation method. The Fe3O4 diffraction patterns have six main peaks at 2θ values of 30.1°, 35.5°, 43.2°, 53.5°, 57°, and 62.8° which corresponding to the reflection from (220), (311), (400), (422), (511), and (440) crystal planes, respectively. Positions and relative intensities of all the peaks are in accordance with the cubic crystalline system of Fe3O4 NPs. Patterns of iron oxides and oxy-hydroxide products of the JCPDS card 79–0418 database were included for comparison [52].
The narrow shape peaks of materials indicate that the synthesized NPs have relatively-high crystallinity, and without the appearance of the impurities phase of goethite α-FeO (OH) and hematite (Fe2O3) corresponding to the diffraction peaks of (110), (104) at 2θ positions of 21.22° and 33.15°.
Broadness of the diffraction peaks was related to particle sizes. Scherer's equation was used to calculate the average particle size D.
In this equation, θ is the angle of the peak, β is the full width at half maximum (FWHM) of the respective XRD peak, λ is the x-ray radiation wave-length in angstroms, and k is a constant. The broadening of Bragg’s peaks indicates the formation of NPs. The calculated mean crystallite size of the synthesized Fe3O4 NPs was about 23.0 nm.
FTIR Spectra Analysis
FTIR was performed to confirm the functional groups on the surface of the synthetic materials. The spectra of pure Fe3O4 NPs and CS-Fe3O4 NPs were shown in Fig. 2. The presence of two strong peaks of Fe3O4 NPs and CS-Fe3O4 NPs at 628.1 and 573.4 cm−1, respectively shows the formation of magnetic NP. Moreover, the band at 573.4 cm−1 was confirmed as the Fe–O stretching vibration of tetrahedral sites of spinel structure [18]. The noted peak at 467.7 cm−1, attributed to the tetrahedral and octahedral sites [53], peak at 3415 cm−1 was due to the O–H stretching model adsorbed on the surface of the Fe3O4 NPs [54]. In the case of CS coated magnetic Fe3O4 NPs, the coating of CS is established by the appearance of the peak at 2923 cm−1 considered to be the stretching vibrations of –CH– in chitosan. The peak at 1634 cm−1 is relevant to the N–H vibration for the chitosan. In addition, the C-N vibration of amino group is at 1416 cm−1 and the C–O in the ether group is at 1071 cm−1.
Scanning Electron Microscopy (SEM) and Transmission Electron Microscopy (TEM) Analysis
Morphological analysis was studied with electron microscopic images. In the SEM images of Fe3O4 NPs, it can be clearly-seen that the particles are uniformly-aggregated, spherical shaped with a grain size 8–25 nm (Fig. 3). SEM images of magnetic uncoated-Fe3O4 NPs and CS-Fe3O4 NPs are shown in Fig. 3. The results suggested that all NPs are most spherical in shape and the grain size of CS-Fe3O4NPs was in the range from 8.0 to 17.0 nm.
From these results, it may indirectly-prove that the magnetic core/shell particles remain single crystals to have an average diameter of 8.0 nm, and (chitosan) shells have the approximate thickness of 9.0 nm. The results suggest that the (chitosan) layer is uniformly-deposited on Fe3O4 NPs, as shown in Fig. 3b.
On the other hand, the TEM images (Fig. 4) of free Fe3O4NPs and CS-Fe3O4NPs reveal that the magnetite NPs are spherical in shape, and the size was ranged from 18.0 nm to 25.0 nm and the average particle size was determined to be 21.0 nm. Also, the immobilized chitosan on Fe3O4 NPs did not lead to the aggregation between the particles and the size did not change. It was concluded that all the chitosan in the final product is chemically-bound (covalent bond) to the Fe3O4 NPs. FTIR spectrum results (Fig. 2) demonstrated that, the precipitation reactions carried out with chitosan rendered Fe3O4 NPs coated by this polymer.
In Vitro Antimicrobial Activity of Free Magnetite NPs and Magnetite NPs Coated with Chitosan
It is remarked from the disc agar distribution method (as a screening procedure) that the CS- Fe3O4 NPs and Fe3O4 NPs represented a qualitative antimicrobial potential toward all the tested bacteria and Candida pathogens. The in-vitro ZOI result verified that CS-Fe3O4 NPs exhibited its encouraged antibacterial activity against E. coli (18.0 mm ZOI; Fig. 5a), and B. subtilis (17.0 mm ZOI; Fig. 5b) as displayed in Table 1.
It worth considering that the antibacterial potency of CS-Fe3O4 NPs was significantly more powerful than Fe3O4 NPs, CS and standard antibacterial agents (Gentamycin; CN).
From our results, the synthesized CS-Fe3O4 NPs show a broad-spectrum antimicrobial activity, but it more active against Gram-negative bacteria more than Gram-positive bacteria.
The activity towards Gram-negative bacteria due to its potential on the cell wall, since it is composed of multi-thin layers of lipopolysaccharide, lipid, and peptidoglycan, while Gram-positive was resistant to the synthesized CS-Fe3O4 NPs due to its cell wall compact structure (solid peptidoglycan layers) [55].
Additionally, the incorporated CS-Fe3O4 NPs were promising antifungal factors, they exhibited tremendous antifungal efficiency upon C. albicans (14.2 mm ZOI; Fig. 5c) as recorded in Table 1.
In our study, there is a relationship between the characteristics of the incorporated CS-Fe3O4 NPs and the antimicrobial effects since, the crystal size of the synthesized CS-Fe3O4 NPs was small (15.0 nm; Fig. 1), dispersed, spherical form with particle size in the nano-scale (21.0 nm; Fig. 4b), and highly-distributed NPs (Fig. 3a) which served as an essential objective in enhancing the antimicrobial potency of CS-Fe3O4 NPs at low concentration (10.0 µg/ml), against all the examined bacteria and Candida sp.
They reported individual physical and chemical properties more than traditional organic and artificial antimicrobial agents such as the decreased crystal sizes and reduced average particle size, more stability and a higher potency for interaction with more further pathogenic bacteria and Candida sp., consequently, increasing their antimicrobial potential [56,57,58].
The MIC results of CS-Fe3O4 NPs against all the tested pathogenic bacteria and Candida sp. were in the range from 10.0 to 0.625 µg/ml as mentioned in Table 1. CS-Fe3O4 NPs possess promising MIC of 0.625 µg/ml against E. coli and B. subtilis.
CS-Fe3O4 NPs size was not simply parameter indicating the antimicrobial characteristics, but other features such as mono-dispersity, simplicity, stability, and the appearance should be considered [58, 59].
The antimicrobial mechanism of the synthesized magnetite NPs needs to be explained in details. There were remarkably suggested mechanisms such as Reactive Oxygen Species (ROS) production (·O2− and ·OH) which depends upon the crystallite size and larger surface area as explained in Fig. 6 [60, 61].
The production of ROS begins when the prepared magnetite NPs within the bacterial cell in the presence of light, which starts to the excitation of the electrons from the valence band to the covalent band with a new energy level which exit h+ in the valence band. Positively, that reaction mechanism explains the band gap effect on the antimicrobial activity [62]. The generated ROS causing serious damage effect when combined with the biological macromolecules inside the bacterial cell such as DNA, lipids, proteins, and carbohydrates (Fig. 6) [63].
El-Batal et al., [64] have claimed that there are four mechanisms interpret the action of metal NPs on the microbial pathogens. They found that Fe metal in magnetite nanosrtucture is started by the adhesion across the surface of the bacterial cell wall and layers (Fig. 6).
After that, they deal with the understanding of nano-metals Fe inside the bacterial cell and cleavage all of the intracellular molecules like biological molecules. Then, the cellular toxicity (oxidative stress) created by the formation of ROS has happened (Fig. 6).
Finally, nano-metals (Fe) were affected against signal transduction pathways. Furthermore, the antibacterial potential of magnetite nanostructure may be due to the interaction with a specific enzyme (that catalyzes mannose-6-phosphate exchange to fructose-6-phosphate) by altering its configuration and subsequent its activity as displayed in Fig. 6. Fructose-6-phosphate is an essential compound in the glycolysis pathway which is connected to the carbohydrate catabolism in all microbes [35].
Photocatalytic Degradation of Chloramine T (CT) Using Magnetite NPs Coated with Chitosan
The photocatalytic activity of the synthesized chitosan coated Fe3O4 nanocomposite was determined using the photocatalytic degradation of CT solution under UV irradiation. Figure 7 illustrates the absorption decline with irradiation time through the photocatalytic degradation of CT solution by (10 mg) of the prepared nanocomposite against (CT) solution (50 ml; 20 mg/L). Upon increasing the irradiation time, the strong absorption bands of CT recorded at 225 nm (indicating the maximum wavelength λmax for the CT) have been continuously-reduced. Absorbance of CT solution was reduced by 86 % after 60 min of UV irradiation at the specified experimental conditions.
Effect of Initial Concentration of CT on Degradation Efficiency
As the initial CT concentration plays a vital role in the photocatalytic degradation process, the effect of ionic strength of CT was studied by varying the initial concentration of CT and keeping other reaction conditions unaltered. Figure 8 represents the variation of degradation capacity as a function of contact time at different initial CT concentration (10, 20, and 30 mg/l). At higher concentration of CT, the degradation capacity was recorded to be high. The higher degradation capacity at higher CT concentration is because of stronger interaction with the nanocomposite at higher ionic concentration of CT.
Effect of pH on Degradation of CT
For photocatalytic degradation studies, one of the vital factors is its dependence on pH of the solution. The effect of initial pH values of CT solution was studied for 90 min of specified experimental conditions (10 mg of the prepared nanocomposite, 50 ml of 20 mg/L CT solution, Temp., = 25 °C). A plot showing the variation of CT removal (%) with time at different solution pH (5.0, 7.0 and 9.0) is exhibited in Fig. 9a. The maximum CT degradation (%) ~ 86.0% in equilibrium was observed at pH 7.0, while, pH 5 and 9 showed degradation efficiencies of 75.5% and 71.5%, respectively. Hence, all the further photocatalytic degradation experiments were conducted at pH 7.0 in this study.
To determine the point of zero charge (PZC) of the CS-Fe3O4 nanocomposite, 0.01 g (CS-Fe3O4 NPs) was added to 50 mL (0.01 M NaCl solution). The pH values of the solutions were adjusted with HCl or Na OH to be as 2, 4, 6, 8, 10, and 12. The samples were stirred at 200 rpm for 48 h. The pH values of the solutions were measured after magnetically-separation of (CS-Fe3O4 NPs). The pH of the PZC value was determined by using a plot which shows the final pH versus initial pH. These results are presented in Fig. 9b.
According to Fig. 9b, the pH of the PZC occurred where there is no significant difference between final and initial pH values, and was determined to be at pH = 8.3. It means that the surface charge of the photocatalyst (CS-Fe3O4 NPs) is positive and negative when pH < pH of PZC and pH > pH PZC, respectively. Besides, when the pH of the solution is equivalent to the pH of the PZC, the photocatalyst surface charge is neutral and the electrostatic force between the photocatalyst surface and ions (CT ions) is negligible [65].
According to the pH of the PZC value, the pH of the PZC regarding CS-Fe3O4 NPs was 8.3, and this result was explained why the photocatalytic degradation of CT was maximum at pH 7.0 as displayed in Fig. 9a. Hence at this point the net surface charge of the CS-Fe3O4 NPs is positive which attracted with the negative charge of CT and improve the photocatalytic degradation of CT.
The photocatalytic degradation of CT began to decrease at pH = 9.0 this occur due to at this point the net surface charge of the CS-Fe3O4 NPs is negative and the repulsion forces between the negative charge of CT and net surface charge of the CS-Fe3O4 nanocomposite which is negative at pH = 9.0. The reason which make the photocatalytic degradation decreases at pH 5.0 unexpectedly is at highly acidic medium the metal oxide leaching may be occur which decrease the catalyst concentration [65]. On the other hand, chitosan contains reactive amino group (–NH2), which is easily protonated to form (-NH3+) in acidic solutions (pH 5.0). The high adsorption capacity is due to the strong electrostatic interaction between the NH3+ of chitosan and negative charge of CT [66], which explains the higher catalytic performance in pH 5 (75.5%) more than the catalytic potential at pH 9 (71.5%).
Effect of the Photocatalyst's Dose on Degradation Efficiency
The effect of nanocomposite dose on the photocatalytic degradation process was studied by keeping other parameters such as initial CT concentration, pH of the solution, and temperature fixed. Figure 10 depicts the effect of photocatalyst dose on CT degradation process, where the dose amount of CS-Fe3O4 NPs was varied (0.1, 0.2 and 0.4) g/L. During this study, the initial concentration of CT was kept constant at 20 mg/l and the pH of the system was kept at 7.0 at 25 °C. It was observed that the percentage degradation of CT significantly-depends on the photocatalyst dose and increases with increasing dose. This direct-proportional between the degradation efficiency and the dose of reaction medium’s photocatalyst can be attributed to the increase in the active sites and large surface area available for CT degradation [67]. From the Fig. 10, it is noticed that percentage degradation of CT approaches nearing 86% at a dose of 2 g/L with the above-mentioned experimental condition.
Kinetic Studies
The degradation rate of CT can be calculated by the following Eq. (3):
where Ct and Co are the remaining and the initial concentrations of Chloramine T, respectively, while (t) is the irradiation time and (k) represent the degradation rate constant.
Figure 11a shows a relation of -ln Ct/C0 vs. time. The results shown that, the kinetics of the degradation reaction followed first-order rate laws (R2 > 98) at initial concentrations.
Moreover, as revealed from Fig. 11b, there is an inverse relation between the apparent first order rate constants and CT initial concentration. This recorded dependence of reaction rate constants on initial concentration is in a good agreement with literature [57, 58, 68].
The proposed reaction mechanism regarding the interaction between the prepared CS-Fe3O4 NPs and CT is shown in Fig. 12, according to our recent published papers [69, 70]. After UV-light excitation of Fe3O4 layer, charge carriers will be photogenerated and redox reactions will be initiated [58]. Then, the generated free radicals (such as OH· And O2·−) will degrade CT into two potential products, p-touluene sulfonamide and hypochlorites that can be easily dissociated into O2 and Cl− ions as shown in Fig. 12. Additionally, the role of CS can be mentioned as they were contains reactive amino group (–NH2), which is easily protonated to form -NH3+, in acidic solutions (pH 5.0). The high adsorption capacity is due to the strong electrostatic interaction between the NH3+ of chitosan and negative charge of CT, as displayed in Fig. 12 [66].
Conclusion
Fe3O4 NPs have been synthesized by a chemical co-precipitation method and characterized by structural and optical tools. The surface of Fe3O4 NPs was stabilized with chitosan (CS) by a direct addition method to obtain modified CS-Fe3O4 NPs. Furthermore, their antimicrobial behavior has been examined against different pathogenic bacteria and yeast which separated from urine samples of UTI-patients. The photocatalytic efficiency of the prepared CS-Fe3O4 NPs was tested against chloramines T (CT). Also, various parameters affecting the efficiency of removal potential such as (pH on adsorption of CT, CT initial concentration, and adsorbent dose) have been studied. Based on XRD, TEM and SEM analyses, it is found that CS-Fe3O4NPs are located at the core, while the CS are coated this core, producing CS-functionalized Fe3O4 NPs with particle size varies from 18.0 nm to 25.0 nm with average particle size at 21.0 nm. The surface behavior reveals in homogeneous grain appearance with remarkable smooth agglomerates can be observed due to the occupation of a large quantity of CS at the grain boundary which could control the grain growth. From FTIR results, the presence of two strong peaks of all materials at 628.1 cm−1 and 573.4 cm−1 shows the formation of magnetic NPs. Moreover, the noted peak at 573.4 cm−1 was confirmed as the Fe–O stretching vibration of tetrahedral sites of spinel structure. The in-vitro ZOI and MIC result verified that CS-functionalized Fe3O4 NPs exhibited its encouraged antimicrobial activity against E. coli (18.0 mm ZOI and 0.625 µg/ml MIC), B. subtilis (17.0 mm ZOI and 0.625 µg/ml MIC), and C. albicans (14.2 mm ZOI and 1.25 µg/ml MIC). So, there is no toxicity regarding the use of CS-Fe3O4 NPs in the different fields. It should be noted that CS-Fe3O4 NPs are also active upon Gram-negative than Gram-positive bacteria. Results obtained from the photodegradation activity indicated that chitosan-coated Fe3O4 NPs (5.0 gm/l) was a promising removal factor achieving 86.0% CT removal in a neutral solution (pH = 7.0). The synthesized CS-Fe3O4NPs are promising for potential applications in industry, food processing and packaging, pharmaceutical uses, wastewater treatment and cosmetics.
Ethical approval:
Not applicable.
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Acknowledgments
The authors would like to thank the Nanotechnology Research Unit (P.I. Prof. Dr. Ahmed I. El-Batal), Drug Microbiology Lab., Drug Radiation Research Department, NCRRT, Egypt, for financing and supporting this study under the project “Nutraceuticals and Functional Foods Production by using Nano/Biotechnological and Irradiation Processes”. Figures 6 and 12 in this paper were created with BioRender.com.
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El-Khawaga, A.M., Farrag, A.A., Elsayed, M.A. et al. Antimicrobial and Photocatalytic Degradation Activities of Chitosan-coated Magnetite Nanocomposite. J Clust Sci 32, 1107–1119 (2021). https://doi.org/10.1007/s10876-020-01869-6
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DOI: https://doi.org/10.1007/s10876-020-01869-6