Abstract
Herein, for the first time, the flower-like enzyme–inorganic hybrid nanoflowers were synthesized using a superoxide dismutase (SOD) as organic material and selected some metal ions (Cu(II), Co(II), Mn(II) and Zn(II)) as inorganic parts at optimum pH value. The synthesis steps of SOD@metalphosphates hybrid nanoflowers were verified by XRD, FT-IR, FESEM, and EDX. The synthesized nanoflowers were utilized as a catalyst in the reduction of organic pollutants (2-nitrophenol (2-NP) and Rhodamine B (RhB)) with NaBH4 in aqueous media for catalytic properties and susceptibility. The activities of both the substrate and the metal center of the catalyst were determined in the increasing rate order of RhB > 2-NP for substrate and SOD@Cu3(PO4)2·3H2O > SOD@Co3(PO4)2·8H2O > SOD@Mn3(PO4)2·7H2O > SOD@Zn3(PO4)2.4H2O hNfs for catalysts. The catalytic data provided herein by using SOD@metalphosphates (SOD@Cu3(PO4)2·3H2O, SOD@Co3(PO4)2·8H2O, SOD@Mn3(PO4)2·7H2O and SOD@Zn3(PO4)2·4H2O) nanoflowers suggest that the materials can be effective catalysts for the water-based reduction reaction of organic pollutants.
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Introduction
Enzymes are proteins that catalyze reactions at very high speeds (Erdem et al. 2015; Arsalan et al. 2020). It is an alternative to chemical catalysts with its features such as high catalytic efficiency and selectivity, low toxicity and water solubility and is widely used in fields such as biochemistry, biomedical, food and chemistry. Enzymes have been recognized remarkably as biocatalysts in various industries due to their green chemistry and substrate specificity. However, free (soluble) forms of enzymes have a short lifetime, and therefore soluble enzymes cannot be exploited on a large scale, limiting their application in many areas and also, the separation of the soluble enzyme from the reaction medium is difficult which makes it impossible to reuse (Madhu and Chakraborty 2017; Zhao et al. 2019). To be used in practice, it is necessary to increase the efficiency, activity, stability, and recovery of enzymes, especially as industrial biocatalysts. To increase the use of enzymes as industrial biocatalysts, stable preparations of enzymes with improved operational stability need to be obtained. Immobilization is one of the important ways enzymes stabilize. Many immobilization methods have been described and used in the literature to overcome possible problems on stability problems of enzymes and to optimize various applications. There are five different approaches in covalent binding, cross-linking, adsorption, arrest, and encapsulation in enzyme immobilization (Wells and Meyer 2014; Shcharbin et al. 2019; Mohamed et al. 2013; Kim et al. 2006). However, in immobilization studies, except for a few enzymes, the activity of the immobilized enzymes increased compared to the free enzyme, but their activity decreased (Sassolas et al. 2012; Netto et al. 2013; Wei et al. 2008). But, first, a new and different immobilized enzyme application with increased efficacy was suggested by Zare et al. (Ge et al. 2012).
Zare et al. reported the formation method of flower-like protein–inorganic hybrid nanoflowers using Cu (II) ion as inorganic components, they are called as “nanoflowers” in the literature, and various proteins and enzymes (lactalbumin, laccase, carbonic anhydrase, lipase, and BSA) as an organic component. In the past few years, the synthesis of enzyme–inorganic hybrid nanostructures has been carried out including pancreatin (a mixture of a-amylase, lipase and protease) (Aydemir et al. 2020), lipase(Wu et al. 2014; Lin, et al. 2014a, b; Lee et al. 2017; Altinkaynak et al. 2020), glucose oxidase (GOD) (Sun et al. 2014), α-amylase(Wang et al. 2013), urease (Somturk et al. 2016), trypsin (Lin, et al. 2014a, b), chymotrypsin (Yin et al. 2015), papain (Liang et al. 2015), laccase (Fu et al. 2019), glucoamylase (Nadar et al. 2016), NADH oxidase (Patel et al. 2017), Cytochrome P450 (He et al. 2017), lactoperoxidase (Altinkaynak et al. 2016), L-asparaginase (Noma et al. 2020), etc.
In principle, the formation of flower-like enzyme–inorganic hybrid nanostructures takes place in three stages: in the first stage, primary metalphosphate crystals are formed depending on the type of metal. Through the coordination of amino groups in the structure of enzymes with metal ions, complexes are formed. In the second stage of growth, large aggregates of biomolecules and primary crystals are formed, flower-like petals appear. In the last step, anisotropic growth causes the formation of a branched flower-like structure. For this reason, the synthesized structures were named “Flower-shaped Hybrid Nanostructures” (Flower-Like Hybrid nanostructures).
Superoxide dismutase (Superoxide Oxidoreductase, E.C: 1.15.1.1, SOD) is a metalloenzyme that catalyzes the dismutation of superoxide anion radicals into molecular oxygen and hydrogen peroxide. This enzyme was detected in oxygen-breathing organisms in 1968 and catalyzes the conversion of superoxide to hydrogen peroxide and molecular oxygen. Hydrogen peroxide is then inactivated by the enzyme glutathione peroxidase and catalase. It plays an important role in controlling superoxide levels in cell divisions (Durak et al. 1996). SOD is found in all cells that metabolize oxygen. It is an important defense against oxygen toxicity (Weselake et al. 1986). The use of SOD as a catalyst and its activity in enzymatic reactions have highlighted its use as a ligand in catalyst chemistry. Herein, SOD@metallophosphate structures with both increased surface area and ligand effect were tested together with metallophosphate structures.
Although the nitro compounds from organic-based paints are used in many industrial applications they are known as important environmental pollutants, and the degradation of these pollutants has recently been preferred. The amino compounds produced as a result of this degradation process are the compounds used in the production of qualified chemicals (Sargin, Baran, and Arslan 2020; Moradi et al. 2020; Xu et al. 2020; Denizalti et al. 2020), which are listed as chelating agents, fibers/nanofibers, agricultural drugs, cosmetics, polymer fabrication, dye-based materials, pharmaceuticals, etc. (Du et al. 2020; Dell'Anna et al. 2014; Das et al. 2019). Also, the studies are carried out to obtain the most ideal catalyst and catalytic conditions in degradation studies and both easily producible and production of high-performance catalysts become important. Recent times, the various metals (copper (Dayan, Altinkaynak, et al. 2020), cobalt (Sheng et al. 2020), palladium (Dayan, et al. 2020a, b, c; Zhang et al. 2020), ruthenium,(Jia, Wang, and Zhi 2020; Liew et al. 2017) silver (Bahadorikhalili et al. 2020; Ansari et al. 2019), nickel (Advani et al. 2020), etc.) as catalysts were tested in the reduction/degradation reactions. The performances of different metals in catalytic reactions are also quite different from each other and high-performance works with low-cost metals are also preferred. The catalytic studies of organic–inorganic hybrid nanoflowers have attracted attention in recent years (Ahmadpoor et al. 2021; Dayan, Altinkaynak, et al. 2020; Alhayali et al. 2021) and the nanoflowers with the obtained organic molecules from plant sources using separation purification processes were fabricated and their catalytic properties were examined (Ahmadpoor et al. 2021).
Herein, for the first time, the flower-like enzyme–inorganic hybrid nanoflowers were synthesized using a superoxide dismutase (SOD) as an organic part and some divalent metal ions (Cu(II), Co(II), Mn(II), and Zn(II)) as inorganic parts at optimum pH value. The fabricated SOD@metalphosphates hybrid nanoflowers as catalysts were used in the degradation of organic pollutants (2-nitrophenol and Rhodamine B). It was determined that the difference of the metal center directly affects the catalytic activity. It is predicted that the catalytic activity may also change with different metals. This is expected and compatible with the Irving-Williams series. Although it is not a surprise, the catalytic activities of nanoflowers with different metals are detailed in this work and this is among the first in the literature.
Experimental
Materials
Superoxide dismutase, albumin from bovine serum (BSA) (lyophilized powder), copper sulfate pentahydrate (CuSO4·5H2O) and zinc acetate dihydrate (Zn(CH3COO)2·2H2O) were purchased from Sigma-Aldrich (USA). Salts (NaCl, KCl, KH2PO4, Na2HPO4, CaCl2·2H2O, and MgCl2·6H2O) were also obtained from Sigma-Aldrich and utilized for the synthesis of the pH solutions. Cobalt(II) sulfate heptahydrate (CoSO4·6H2O) was obtained from across organics and manganese(II) sulfate monohydrate (MnSO4·H2O) was obtained from bioshop. Ultrapure water was used to prepare aqueous solutions throughout the work.
Synthesis of SOD@metalphosphates hybrid nanoflowers
SOD@metalphosphates hybrid nanoflowers (SOD@metalphosphates hNfs) were prepared according to two different methods depending on the type of metal ion (Cu(II), Co(II), Mn(II) and Zn(II)) (Gao et al. 2020; Somturk et al. 2016). In the first method (for Cu(II) and Mn(II) ions), CuSO4·5H2O and MnSO4·H2O (120 mM) solutions were prepared using purified water. A certain volume of this solution was then added to 10 mM PBS (phosphate-buffered saline) solution (pH 7.4), including 0.02 mg mL−1 SOD. The mixture was vortexed vigorously for 30 s and incubated without disturbing for 3 days at + 4 °C (Fig. 1 (a)). After incubation period, to obtain precipitates, each reaction tube was centrifuged at 10.000 rpm for 15 min. Finally, the collected SOD@metalphosphates hNFs were dried at room temperature.
In the second method (for Co(II) and Zn(II) ions), SOD@metalphosphates hNfs were synthesized based on a method determined by Zhang et al. and making some modifications (Zhang et al. 2016; Kim et al. 2016). For this purpose, Zn(CH3COO)2·2H2O and Co(NO3)2·6H2O (0.05 g/L) solutions were prepared. After that, 16 mg SOD and a certain volume of metal ion solution were added into 20 mL phosphate buffer saline solution (pH 7.4). The mixtures were left on the magnetic stirrer for 24 h at room temperature. After incubation, they were centrifuged at 10.000 rpm for 15 min. Finally, the collected SOD@inorganic hybrid nanoflowers were dried at room temperature (Fig. 1 (b)).
Characterization of SOD@metalphosphates hNfs
The surface morphologies of the fabricated SOD@metalphosphates hNfs were recorded by using field emission scanning electron microscope (FESEM, Zeiss GeminiSEM 500). The elemental weight and atomic percentage analyses of Cu, Co, Zn, and Mn elements (also other elements such as N, P, and O from the organic materials (SOD) and phosphate group) in SOD@metalphosphates hNFs were separately assigned by the energy-dispersive X-ray (EDX) technique. The chemical-crystal structure of SOD@metalphosphates hNfs was analyzed by using X-ray diffraction (Malvern Panalytical XRD) and Fourier transform infrared spectroscopy (FT-IR) (PerkinElmer Spectrum 400). Size analysis of hybrid nanostructures was determined using the Image ProPlas 6.0 program. At the same time, the protein content of SOD@metalphosphates hNfs was determined using Bradford method (Somturk et al. 2016). The encapsulation rate was determined for the synthesized SOD@metalphosphates hNfs. The encapsulation rates were determined to vary between 87 and 95%.
The testing of SOD@metalphosphates hNfs as a catalyst
The catalytic activities of SOD@metalphosphates hNfs were evaluated in the reduction of 2-nitrophenol (2-NP) and Rhodamine B (RhB) using NaBH4 ion as a hydrogen source at ambient temperature with an aqueous solution.
In a typical reaction, a 1.0 mg of the SOD@metalphosphates hNfs was first prepared and added to the solution of nitrophenols or dyes and NaBH4 (0.03 M, freshly, optimum concentration (Dayan, Altinkaynak, et al. 2020; Dayan, Kayaci, Dayan, et al. 2020a, b, c; Dayan et al. 2015a, b; Dayan et al. 2015a, b) in deionized water (10 mL) at ambient temperature and stirred in a clean tube. After the desired time, the reaction samples of the catalytic mixture as a small amount were taken out of the tube and filtered through the micro-column with cotton for the measurement of the absorbance spectra. The catalytic efficiencies of the SOD@metalphosphates hNfs catalysts were seen by comparing the bands which appeared and disappeared after reduction on the UV–Vis spectrum.
Results and discussion
The specific surface morphologies of the fabricated SOD@metalphosphates hNfs in pH 7.4 at room temperature were evaluated by FESEM analysis and the images were confirmed to be flower-like (known as nanoflowers). Average nanoflower dimensions for the SOD@Cu3(PO4)2·3H2O·hNfs, SOD@Co3(PO4)2·8H2O hNfs, SOD@Mn3(PO4)2·7H2O hNfs and SOD@Zn3(PO4)2·4H2O hNfs were recorded as ∼ 7.11 μm, ∼ 8.97 μm, ∼ 10.29 μm, ∼ 2.23 μm, respectively (Fig. 2). As seen in Fig. 2, as the metal content changes, there are obvious differences in FESEM images. Also, all the materials were recorded to be in a sphere type formation and FESEM images were reported as a visual counterpart of the effect of metal centers on physico-chemical parameters. Herein, the metal (II) ions with the phosphate source form metallophosphates and a specific crystallization occurs during this formation. Especially in the presence of ligand (enzyme or organic molecules), these morphologies differentiate further and the materials are known as nanoflowers. These morphologies depend on the metal ion and ligand, and a coordination bond is formed between metal ions and groups such as N, S and O on ligands and increases the stability of the material.
The elemental composition of the SOD@metalphosphates hNfs was analyzed by the energy-dispersive X-ray (EDX) technique (Fig. 3). The founded elements are suitable to Cu3(PO4)2·3H2O, Co3(PO4)2·8H2O, Zn3(PO4)2·4H2O, Mn3(PO4)2·7H2O nanocrystal structures (Cu, Co, Zn, Mn, O, and P) and the superoxide dismutase (SOD) (C and N). These EDX peaks were confirmed the formation of the SOD@metalphosphates hNfs structures and the EDX spectrum demonstrated that the average weight and atomic percentages of copper for SOD@Cu3(PO4)2.3H2O hNfs, cobalt for SOD@Co3(PO4)2·8H2O hNfs, zinc for SOD@Zn3(PO4)2·4H2O hNfs, manganese for SOD@Mn3(PO4)2·7H2O hNfs were recorded as 21.7% and 6.7%, 36.5% and 15.3%, 29.4% and 9.0%, 31.8%, and 14.6%, respectively.
Also, the elemental mapping of SOD@metalphosphates hNfs was performed (Fig. 4) and it can be considered as one of the strongest pieces of evidence for the formation of SOD@metalphosphates hNfs. As seen in Fig. 5, the elemental mapping analyses confirm the Cu, Co, Zn, Mn, N, O, and P elements, and the elements are homogeneously distributed inside the SOD@metalphosphates hNfs.
The chemical structure and formation of SOD@metalphosphates hNfs were investigated using the FT-IR (Perkin Elmer Spectrum 400) spectrum. The FT-IR spectrum revealed characteristic peaks of SOD@metalphosphates hNfs (Fig. 5). The data of spectrums of free SOD and SOD@metalphosphates hNfs nanoflowers were seen as follows; For free SOD, FT-IR (cm−1): 3270 (N–H and O–H stretching), 3074 (Ar–H, stretching), 2962 (C–H, stretching), 2933 (C–H, stretching), 2872 (C–H, stretching), 1633, 1515, 1449, 1392, 1339, 1309, 1286, 1229, 1159, 1101, 1052, 1026, 931, 821, 736, 695, 665, 642, 623, 604, 575, 543, 525, 488, 470. For SOD@Cu3(PO4)2.3H2O hNfs, FT-IR (cm−1): 3303 (N–H and O–H stretching), 2979 (Ar–H and C–H stretching), 2900 (C–H, stretching), 1622, 1541, 1410, 1150, 1041 (P=O), 986, 956 (P–O), 799, 617 (O=P=O), 591, 556 (O=P=O), 504, 492, 483, 475, 467. For SOD@·Co3(PO4)2·8H2O hNfs, FT-IR (cm−1): 3444 (N–H and O–H stretching), 3191 (Ar–H, stretching), 3046 (C–H, stretching), 1646, 1549, 1396, 1339, 1031 (P=O), 970 (P–O), 937, 832, 694 (O=P=O), 667, 615, 567, 536 (O=P=O), 504, 496, 491, 473, 466, 456. For SOD@Zn3(PO4)2.4H2O hNfs, FT-IR (cm−1): 3531 (N–H and O–H stretching), 3270 (Ar–H, stretching), 3184 (Ar–H, stretching), 2964 (C–H, stretching), 2925 (C–H, stretching), 1645, 1534, 1449, 1402, 1244, 1102, 1065, 1020 (P=O), 999 (P=O), 931 (P–O), 708, 672, 628 (O=P=O), 595, 585, 563 (O=P=O), 535, 519, 507, 497, 489, 480, 473, 455. For SOD@Mn3(PO4)2.7H2O hNfs, FT-IR (cm−1): 3600–3200 (N–H and O–H stretching), 3193 (Ar–H, stretching), 2967 (C–H, stretching), 2921 (C–H, stretching), 1634, 1535, 1447, 1404, 1318, 1247, 978 (P=O), 948 (P–O), 810, 752, 689, 666, 542 (O=P=O), 495, 473, 453. The presence of metallophosphate structures can be easily detected in hybrid nanoflowers with the formation of phosphorus and oxygen bonds. The bending vibrations of O=P=O groups in SOD@metalphosphates hNfs were recorded at ∼ 551 cm−1 and ∼ 599 cm−1. The P=O and P–O tension bands appeared at ∼ 1042 cm−1 and ∼ 954 cm−1. The detection of phosphorus–oxygen bonds indicates the formation of metallophosphates, and the frequency shift in the vibrations of these bonds is an indication of the bonding of different metals. It is also a critical indicator for the characterization of a newly formed bond structure relative to the free SOD. Also, the presence of peaks belonging to functional groups originating from SOD in hybrid nanomaterial structures is another confirmation part of the structure. The vibration bands of typical SOD at 1400–1633 cm−1 are bound to the NH2, C=C and C=N groups, and the tensile bands at 2800–3000 cm−1 are bound to the –CH2 and –CH3 groups.
The powder X-ray diffraction data of the synthesized SOD@metalphosphates hNfs were carried out to determine the crystal structure of nanomaterials (Fig. 6). The XRD peaks were assigned as for SOD@Cu3(PO4)2·3H2O hNfs, XRD: 9.10°, 12.96°, 18.79°, 20.87°, 27.38°, 29.48°, 30.64°, 31.74°, 33.71°, 37.21°, 41.59°, 45.48°, 47.74°, 53.46°, 56.48°, 61.10°, 63.57°, 66.22°, 68.19°, 71.42°, 75.26°, 79.06°, 83.95° in Fig. 6(a) compared with JCPDS (00 − 022 − 0548), and for SOD@Co3(PO4)2.8H2O hNfs, XRD: 11.29°, 13.34°, 18.38°, 19.66°, 22.05°, 23.26°, 28.02°, 30.35°, 31.74°, 33.24°, 35.81°, 37.42°, 39.16°, 41.59°, 43.85°, 45.53°, 47.37°, 51.83°, 55.27°, 58.87°, 61.50°, 63.15°, 66.22°, 70.69°, 77.62° in Fig. 6(b) compared with JCPDS (00 − 041 − 0375) and for SOD@Zn3(PO4)2·4H2O hNfs, XRD: 9.68°, 16.83°, 17.54°, 18.35°, 19.45°, 20.21°, 22.21°, 22.99°, 24.55°, 25.83°, 26.36°, 27.46°, 28.67°, 31.48°, 33.95°, 34.45°, 35.79°, 37.18°, 38.49°, 39.73°, 41.20°, 41.99°, 43.12°, 45.47°, 46.92°, 50.07°, 52.99°, 54.23°, 55.06°, 56.37°, 57.87°, 59.11°, 60.60°, 61.34°, 66.12°, 69.35°, 71.42°, 75.07°, 77.07°, 82.11° in Fig. 6(c) compared with JCPDS (01 − 076 − 0896), and for SOD@Mn3(PO4)2·7H2O hNfs, XRD: 7.87°, 10.34°, 12.86°, 17.33°, 22.11°, 23.16°, 26.33°, 28.12°, 29.15°, 30.06°, 31.45°, 32.19°, 33.03°, 34.37°, 35.19°, 36.02°, 38.05°, 42.11°, 43.50°, 44.17°, 50.94°, 52.77°, 53.98°, 56.93°, 60.73°, 65.57°, 69.90° in Fig. 6(d) compared with JCPDS (00 − 003 − 0020). All XRD pattern were compared with metallophosphate structures and indexed with JCPDS numbers, and the difference of each powder pattern was recorded with 2-theta degrees. Due to the small amount of SOD used in the synthesis conditions, the peaks from SOD could not be observed clearly. All these data were recorded in accordance with the proposed structure.
Model tests for catalytic properties
The catalytic reduction reaction of the nitrophenols or organic dye to related products by various catalysts, which are mostly noble metal complexes or material/composite, is being considered as a green process with different reaction conditions. However, the catalysts bearing noble metal are expensive and unsustainable. They are also used in many technological fields and applications. Moreover, scientists are required to introduce new methodologies and catalytic systems that are eco-friendly and cost-effective in the reduction reaction of organic pollutants to corresponding reduced products. Herein, we purposed or proposed the catalytic efficiencies of SOD@metalphosphates hNfs in the reduction of 2-nitrophenol (2-NP) and Rhodamine B (RhB) with BH4− ion as a hydrogen source in the aqueous media at ambient temperature. The absorption spectra of catalytic reactions were monitored at a regular interval of time after the reaction steps (the testing procedure). The sample spectra were recorded from the 0 s to final times in the range of 300–600 nm for 2-NP and 400–700 nm for RhB.
Firstly, the 2-nitrophenolate (2-NP) reactant (5.0 × 10–4 M) having absorption bands at λmax = 414 nm (-NO2 group of 2-NP) as a yellow color of the solution relating to the 2-nitrophenolate and the color gradually vanished due to the 2-aminophenol product. The final conversions were recorded at 60 s, 180 s, and 300 s and founded as 40.4%, 92.4%, 93.5% for SOD@Cu3(PO4)2·3H2O hNfs, 22.1%, 26.6%, 32.1% SOD@Co3(PO4)2.8H2O hNfs, 15.1%, 16.2%, 18.8% for SOD@Zn3(PO4)2.4H2O hNfs and 15.2%, 16.3%, 20.1% for SOD@Mn3(PO4)2.7H2O hNfs, respectively (Fig. 7). According to the obtained data, the catalytic activity order of SOD@metal (II) (Cu(II), Co(II), Zn(II), and Mn(II)) nanoflowers is as follows; SOD@Cu3(PO4)2.3H2O hNfs > SOD@Co3(PO4)2.8H2O hNfs > SOD@Mn3(PO4)2.7H2O hNfs > SOD@Zn3(PO4)2.4H2O hNfs. Herein, the SOD@Cu(II) hNfs catalyst is 2.5 × superior to others (Co(II), Zn(II), and Mn(II) nanoflowers). This study is a strong indicator that catalytic activities of nanoflowers, which use the same enzyme and solutions, change dramatically with the different metals (Cu(II), Co(II), Zn(II), and Mn(II)).
Catalytic tests were also performed for Rhodamine B, which is an organic contaminant commonly used to perform a similar comparison. The main purpose here is to check if there is a change in the most active catalyst sequence when different substrates are used. It is also to clarify the effect of changes in metal centers of the fabricated nanoflowers. Figure 8 shows the Rhodamine B (RhB) reduction reaction by BH4− as hydrogen source while using the SOD@metalphosphates hNfs (Cu(II), Co(II), Zn(II), and Mn(II)) as effective catalysts. The aqueous solution of Rhodamine B (Rh B) demonstrated a broad and distinct peak at 550 nm in its UV–Vis spectra. All the materials (SOD@metalphosphates (Cu(II), Co(II), Zn(II), and Mn(II)) hNfs) catalyzed the Rh B reduction process by basic stirring at ambient temperature and the 550 nm peak disappearance was considered due to the reduction mechanism.
For the reduction process of Rh B, the catalytic conversions at 60 s and 900 s were achieved as 45.0%, 94.3% for SOD@Cu3(PO4)2.3H2O hNfs, 34.1%, 82.4% for SOD@Co3(PO4)2.8H2O hNfs, 32.1%, 33.2% for SOD@Zn3(PO4)2.4H2O hNfs, 29.6%, 50.1% for SOD@Mn3(PO4)2.7H2O hNfs, and 26.4%, 57.9% for SOD-free. Likewise, the catalytic efficiencies order of SOD@Metal(II) (Cu(II), Co(II), Zn(II), and Mn(II)) materials in the reduction of Rh B is as follows; SOD@Cu3(PO4)2.3H2O hNfs > SOD@Co3(PO4)2.8H2O hNfs > SOD@Mn3(PO4)2.7H2O hNfs > SOD@Zn3(PO4)2.4H2O hNfs > SOD-free.
Herein, it was noteworthy that both nitrophenol and Rhodamine B substrate had the same catalytic sequence. This explains that the metal center has a significant effect on the catalytic cycle. In our previous studies, we have partially demonstrated an increase in performance due to the difference in the metal center (Dayan, Altinkaynak, et al. 2020). In this study, we have seen that when we compare four different metals, their tendency in the reduction reaction is the same even if the substrate changes. However, different catalytic trends can be observed by performing experiments on different substrates. Kinetic parameters were calculated to analyze the results in detail and compare them with the literature.
To determine the kinetic equation for the reduction of organic pollutants, the λmax (nm) values were created due to the corresponding equation; ln (Ct/C0) = − kt, where t is time for the catalytic reaction and, k is the apparent first‐order rate constant (s−1) in Table 1. In the kinetic equation, C0 and Ct values were calculated the absorbance values were noted by spectrophotometrically at the desired time (t) and k. Also, the k' = k/M parameters (M: the amount of the catalyst) were calculated for quantitative comparison and the values were determined as the ratio of the rate constant k to the weight of the catalyst added (Kamal 2019; Liang et al. 2018; Ahsan et al. 2019). All the parameters of SOD@metalphosphates (Cu(II), Co(II), Zn(II) and Mn(II)) hNfs are compared in Table 1.
Considering the kinetic parameters, it is clear that the material SOD@Cu3(PO4)2·3H2O hNfs was found as an effective catalyst in the reduction of both 2-nitrophenol and Rhodamine B substrate. This performance is demonstrated by kinetic plots of ln (Ct/C0) vs. reaction time in Fig. 9.
Catalytic efficiency or activity depends both on the catalyst and on the substrates, media, reaction conditions (Hatamifard et al. 2016; Zhang et al. 2019; Li et al. 2020; Mwansa and Page 2020). The system is designed according to many parameters such as a surface area for materials, difference of functional groups, particle size, solubility, stability, surface morphology and redox potentials of metal ions (Goyal et al. 2014; Khodadadi et al. 2017; Hatamifard et al. 2015; Sajjadi, Nasrollahzadeh, and Tahsili 2019; Mateen et al. 2019; Guo et al. 2020; Zhu et al. 2020). The nanocomposite/materials containing metal ions have been recorded many times as effective catalysts in the reduction reactions of nitro compounds (Liu et al. 2018; Cui et al. 2018; Begum et al. 2016; Huang et al. 2018; Shokouhimehr 2015; Nasrollahzadeh et al. 2018; Dileepkumar et al. 2020; Attatsi and Nsiah 2020; Tijani et al. 2019; Mei et al. 2019; Azadbakht et al. 2020; Shao and Sadeghzadeh 2021). Many alternative reaction mechanisms for the reduction of nitro compounds have also been proposed by scientists (Mahata et al. 2008; El-Hout et al. 2015; de Loera et al. 2018; Liu et al. 2020).
The catalytic mechanism for the reduction of organic pollutants with NaBH4 in water has been extensively documented in earlier reports (Kamal et al. 2017, 2016). For these catalytic cycles, it is stated that the substrate (anion or cation) and the BH4− ions adsorb on the catalytic material surface for heterogeneous catalysts. Herein, the metal ions (Cu(II), Co(II), Zn(II), and Mn(II)) onto the SOD enzyme and phosphate ligand played a catalytic center. The metal ions (Cu(II), Co(II), Zn(II), and Mn(II)) simply facilitate the electron transfer from the adsorbed BH4− ions to the corresponding substrate. We observed the effect of different metals on catalytic activity and revealed this difference with their results. We anticipate that the catalytic activity of such nanoflowers can be increased with different modifications. It is also known that the SOD molecule is reduced by NaBH4 (Viglino et al. 1985). It may also be possible for many macromolecules or ligands, such as the SOD. Herein, the SOD molecule is isolated as a stable nanomaterial in the form of hybrid material before being added to the same medium as NaBH4. At the same time, the concentrations of both the SOD molecule and NaBH4 are low in the catalytic system. For this reason, it is thought that it will not affect the performance of the catalyst to a large extent.
For catalytic efficiency of the synthesized SOD@Cu3(PO4)2·3H2O hNfs hybrid materials, a reusability (recycling) study for 2-nitrophenol (2-NP) at 300 s were performed as 5 × in the optimized (same) reaction conditions (In each reaction, the catalysts were centrifuged and washed with deionized water (3 × 2 ml).) (% Conversion = ([A0–At]/A0) × 100, A0 is the absorbance at time (t = 0) (Fig. 10). The recycles (I–V) were recorded as 93.5%, 85.1%, 74.5%, 69.7%, 61.7% (the performance loss was achieved in the last 2 cycles). With respect to the reusability study, the conversions were found to be good-moderate results and if developed, it may be suitable for economic purposes as well. The FT-IR spectrum after the recycling work of SOD@Cu3(PO4)2·3H2O hNfs hybrid materials are given in Figure S1. The metallophosphate structures are generally known to be insoluble in aqueous media. Some differences in these solubility levels may also occur due to the ligand effect. However, it was recorded that the catalyst showed moderate performance and stability in aqueous media.
In our previous studies, it was determined that the nanoflowers used for this purpose retained their chemical structures despite losing their morphological structures (Alhayali et al. 2021; Dayan, Altinkaynak, et al. 2020). Likewise, it was noted that the chemical structure of the hybrid material was preserved here as well.
The use of hybrid nanoflowers with NaBH4 in reduction reactions was carried out for the first time by our research group (Dayan, Altinkaynak, et al. 2020) and, the catalytic substrates such as 2-nitroaniline, 4-nitroaniline, nitrobenzene were used in our studies (Dayan, Altinkaynak, et al. 2020; Alhayali et al. 2021). In this work, both 2-nitrophenol as another nitroarene group, and Rhodamine B as an organic pollutant, were tested in the degradation reactions. We developed and diversified our catalyst design with the experience we gained from our previous work. We have already seen that the metal center actively plays a role in catalytic activity.
Similarly, herein, it was noted that Cu, Co, Zn, and Mn metal ions had different catalytic activities. It was also found that the SOD enzyme, as an organic group, had an activity alone. When the data in here were evaluated, both a decrease in reaction times and a significant increase in conversion percentage were noted in terms of catalytic performance. Compared to Catalase/Fe3O4@Cu2+ hNFs at pH 7.4, TPP@CuhNfs, and TPP@CohNfs catalysts that we have produced previously, the performance of our most active catalyst (SOD@Cu3(PO4)2.3H2O hNfs) in this work is a quite good catalyst (Table 2). Thus, the production of a higher performance catalyst has been made possible compared to its counterparts in the literature.
Conclusion
To summarize, we have fabricated an eco-friendly approach to forming the phenomena named organic–inorganic hybrid nanoflower from superoxide dismutase (SOD), phosphate-buffered saline (PBS), Cu(II), Co(II), Zn(II), and Mn(II) salts as starting materials. The characterization analyses of the fabricated SOD@metalphosphates (Cu(II), Co(II), Zn(II), and Mn(II)) hNfs were performed by FESEM, EDX, XRD, FT-IR methods and the results confirm that the SOD macromolecule assembled on the Metal(II) hNfs. Also, we tested all the fabricated SOD@ SOD@metalphosphates (Cu(II), Co(II), Zn(II), and Mn(II)) hNfs as a catalyst in the one-pot reduction reaction of 2-nitrophenol and Rhodamine B in the water at ambient temperature. Herein, the catalytic efficiency of the SOD@metalphosphates (Cu(II), Co(II), Zn(II), and Mn(II)) hNfs has been recorded to be regarding the metal ion center types of the fabricated nanoflowers. The catalytic activity ranking for both substrates was found as SOD@Cu3(PO4)2·3H2O hNfs > SOD@Co3(PO4)2·8H2O hNfs > SOD@Mn3(PO4)2·7H2O hNfs > SOD@Zn3(PO4)2·4H2O hNfs. The facile and ecological approach to fabricating nanoflowers demonstrates that these materials can have high catalytic activity in short-time and water at ambient temperature.
Data availability
The data that support the findings of this study are available from the corresponding author upon reasonable request.
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This study was supported by Erciyes University Scientific Research Projects Unit with the project coded FDK-2016-6637 and was conducted at the Department of Chemistry, Erciyes University.
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Somtürk Yılmaz, B., Dayan, S., Özdemir, N. et al. Catalytic performance improvement with metal ion changes for efficient, stable, and reusable superoxide dismutase–metalphosphates hybrid nanoflowers. Chem. Pap. 76, 4245–4260 (2022). https://doi.org/10.1007/s11696-022-02179-z
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DOI: https://doi.org/10.1007/s11696-022-02179-z