Synthesis, Characterisation, DFT Studies and Electrochemical and Biological Application Studies of a New Schiff Base Based on from Naphthalene-1, 8-Diamine and its Co(II), Ni(II), Cu(II) and Zn(II) Complexes
Geetha Thamaraichelvan and Santhi Sambamoorthy*
Department of Chemistry, Seethalakshmi Ramaswami College, Affiliated to Bharathidasan University, Tiruchirappalli, Tamil Nadu, India.
Corresponding Author E-mail: santhi.muthuraman@yahoo.com
Article Received on : 22 Jul 2024
Article Accepted on :
Article Published : 13 Nov 2024
Reviewed by: Dr. Wayan Sutapa
Second Review by: Dr. Anshul Singh
Final Approval by: Dr. Ioana Stanciu
A new Schiff base 4,4’-((naphthalene-1,8-diylbis(azanylylidene))bis(methanylylidene)) diphenol (NDBDP) has been synthesized from 4-hydroxybenzaldehyde and 1,8-diaminonaphthalene and characterised by Infrared, Ultraviolet-Visible, Proton-1 Nuclear Magnetic Resonance, Carbon-13 Nuclear Magnetic Resonance and mass spectral studies. Further, the Schiff base has been complexated with Cobalt(II),Nickel(II),Copper(II) and Zinc(II). All the synthesised complexes are established as neutral complexes based on various spectral, analytical and magnetic behavioral studies. The redox property of all the metal Schiff base complexes have been explored through cyclic voltammetry analysis. Density Functional Theory (DFT) studies have been performed using GAUSSIAN09W program with B3LYP/6-31G (d,p) as the basis set to substantiate the structure of Schiff base NDBDP. The synthesized Schiff base and its transition metal complexes have been scrutinised for their biopotency namely antimicrobial, anti-inflammatory and antioxidant activities. The complex [Cu(NDBDP)2] is found to possess high antioxidant activity. The cytotoxic behaviour of the [Cu(NDBDP)2] complex was scrutinized in MCF-7 (human breast cancer cell lines) which indicate the moderate cytotoxic behaviour of the complex.
KEYWORDS:Anticancer; Antioxidant; Anti-inflammatory; Metal Complexes; Schiff base
Download this article as:Copy the following to cite this article: Thamaraichelvan G, Sambamoorthy S. Synthesis, Characterisation, DFT Studies and Electrochemical and Biological Application Studies of a New Schiff Base Based on from Naphthalene-1, 8-Diamine and its Co(II), Ni(II), Cu(II) and Zn(II) Complexes. Orient J Chem 2024;40(6). |
Copy the following to cite this URL: Thamaraichelvan G, Sambamoorthy S. Synthesis, Characterisation, DFT Studies and Electrochemical and Biological Application Studies of a New Schiff Base Based on from Naphthalene-1, 8-Diamine and its Co(II), Ni(II), Cu(II) and Zn(II) Complexes. Orient J Chem 2024;40(6). Available from: https://bit.ly/4g2V48b |
Introduction
Organic reactions involving the condensation of two or more molecules produce novel compounds with high biological behaviors. Schiff bases are significant because of their activity to stabilize metal ions of different oxidation states, broad range of biological spectrum and their involvement in various industrial and catalytic applications. Because of the presence of a lone pair of electrons on the azomethine group (-N=CH) Schiff bases form stable complexes with metal ions. Imine complexes possess biological applications such as antimicrobial1,2, antiviral 3, anticancer 4, antitumor 5, antioxidant 6 and anti-inflammatory activities 7. Furthermore, imine complexes are applied in immobilization of enzymes. The biopotency 8 of Schiff bases is possible because of the presence of azomethine group present in Schiff bases. The simple synthetic routes and the wide applications in numerous areas, including biology, make Schiff bases and their metal complexes find a conspicuous place in research.
With the above facts in mind, in the present study, a new Schiff base was suitably designed and synthesized by the reaction between of 4-hydroxybenzaldehyde and naphthalene –1,8 – diamine. The Cobalt (II), Nickel (II), Copper (II) and Zinc (II) complexes of the Schiff base have also been synthesized. The Schiff base was assigned a suitable structure based on various spectral studies. DFT calculations were manipulated to support the assigned structure of the Schiff base. Estimation of metal percentage, thermal analysis, conductance quantification and different spectral recordings (IR, UV-Vis & EPR at LNT) were executed for all the synthesized complexes. Based on the results, suitable structures were assigned to the complexes. The redox properties of all the complexes were also studied to establish the catalytic application. The biological applications like antifungal, antibacterial, antioxidant and anti-inflammatory activities were studied for all the synthesized; compounds, and anticancer activity for the Cu (II) complex was delineated.
Experimental Methods
Spectral and Analytical Studies
The IR spectrum of the compounds was recorded with FT-IR spectrophotometer (model; Spectrum RXI), NMR spectrum with BRUKER AVIII500 and BRUKER AVIII HD and UV-Visible spectra with Perkin Elmer Spectrometer. The mass spectrum of the Schiff base was taken with a Q-T Mass spectrometer in Electro Spray Ionization (ESI). JES; FA200 spectrometer was used for recording the EPR spectrum of the copper complex. TGA/DTA analyses were performed in the temperature ranging from 40 to 730 °C. The Elico conductivity bridge was used to determine the molar conductance of all four synthesized complexes in DMSO medium at a concentration of about 10-3 M. Standard procedures were adopted for metal estimation studies. The magnetic property was analysed with Gouy Balance. The redox properties of all four complexes were analysed at room temperature. The electrodes used are glassy electrode, silver-silver chloride electrode and platinum electrodes. During the study, tetrabutylammonium perchlorate was used as a supporting electrolyte.
Biological Activity Antimicrobial Activity
The antifungal and antibacterial properties of all the synthesized compounds were analyzed in an agar medium following a good diffusion method. The bacterial pathogens taken for the study were Staphylococcus aureus and Klebsiella pneumoniae and the fungal pathogens studied were candida albicans and Aspergillus niger. The diameter zone of inhibition revealed the bio potency of the compounds.
Antioxidant Activity
For the study of antioxidant property DPPH scavenger assessment is applied. DPPH is an easily available and stable organic nitrogen radical λ max of DPPH is 517 nm. A change of color from purple to yellow is observed indicating the absorption of hydrogen atom. The absorption at 517 nm decreases corresponding to the increase of antioxidant potential. For the execution of analysis, DPPH solution of 0.1 mM in methanol is prepared for which 39 mg of DPPH is taken in 100 ml of methanol. This solution is kept at -20 °C. Ascorbic acid (1 mg in 1 ml) is used as the standard. Samples of varying strength namely 500, 250, 100, 50 and 10 μg /ml are subjected to analysis. Each time 300 μl of the sample 100 μl of DPPH solution is added, shaken well and kept aside for 30 minutes under room temperature. Finally, the absorbance was recorded by keeping the λ max at 517 nm. Scavenging effect = % inhibition = [(absorbance of control- absorbance of reaction mixture)/absorbance of control] X 100. Graph Pad Prism 6.0 software (USA) is utilized for calculation of % inhibition and IC50 value.
Anti-inflammatory Activity
Inflammation is caused by protein denaturation. Anti-inflammatory activity is nothing but inhibition of the above-mentioned denaturation. For this study, the method developed by Mizushima and Kobayashi and Sakat et al. were followed. Acetyl salicylic acid (Sigma Aldrich) was taken as the standard. The Schiff base NDBDP was taken at various strength namely 500, 250, 100, 50 and 10 μg/ml. To each test sample 500 μl of 1% bovine serum albumin (Himeda, India) was added. All the test mixtures were heated 20 minutes at 51°C after keeping at room temperature for 10 minutes. Absorbance was measured at 660 nm after the samples cool down to room temperature. The formula adopted for calculation is,
% Inhibition=100−((A1-A2)/A0) *100)
A1 – absorbance of control, A2 – absorbance of test sample and A0 – absorbance of positive control
The analysis was done in triplicate and the results are averaged.
Anticancer Activity
A 10% FBS, 100 ug/ml of the antibiotic penicillin, and 100 µg/ml of streptomycin were added to liquid DMEM. The above mixture is kept under an atmosphere of CO2 at 310 K. This medium was used for culturing MCF-7 cells bought from NCCS, Pune. With the help of MTT assay, using MCF-7 cells, the in vitro cytotoxicity of the copper complex was explored. The cancer cells cultured as above were taken in a tube and harvested by trypsinization. A tissue culture plate in DMEM was saturated with 10 % FBS and 1% antibiotic solution for a period of 48 hours at 310 K. Sterile PBS was used to wash the wells. Copper complex solutions of different concentrations were then applied in the DMEM medium having no serum. A 5% CO2 humidified incubator was used for the incubation of cells. The incubation was done for 24 hours at 310 K. Each well 20 µL of MTT was added at the end of the incubation period.
Synthesis of Schiff base NDBDP and its Metal Complexes
Naphthalene-1,8-diamine (0.1 mmol) dissolved in 30 ml of ethanol and 4-hydroxy benzaldehyde (0.2 mmol) in 30 ml ethanol were mixed and stirred for 2 hours under room temperature. The dark blue powder deposited was filtered and washed with a pet. ether. DMSO is a suitable solvent for the Schiff base. The melting point is 188°C.
The Schiff base NDBDP (0.2 mmol) and the respective metal chlorides (0.1 mmol) (CoCl2, NiCl2, CuCl2 & ZnCl2) were refluxed in ethanol at a temperature of 60 °C for 3 Hours. The complexes formed were filtered and dried. DMSO is found to be a suitable solvent for all the complexes. The decomposition of all 257 °C for Co complex, 250 °C for Ni complex, 238 °C for Cu complex and 220 °C for Zn complex.
Results and Discussion
Characterization of Schiff base NDBDP and its Metal complexes
FT-IR spectra
The presence of phenolic group 9 is specified by the absorption band at 3415.14 cm-1. It also shows that the phenolic group is involved in inter-molecular hydrogen bonding. The absorption bands at 1514.42 cm-1 and 1444.37 cm-1 corresponding 10 to C=C stretching authenticate the aromatic nature of the compound. The aromatic nature is further substantiated by the peaks ranging from 830.93cm-1 to 761.04cm-1. The >C=N group is confirmed by its stretching vibration band appeared 11 at 1647.57 cm-1.
The stretching vibration of the >C=N group occurring at 1647.57 cm-1 in the Schiff base is shifted to 1630.13-1642.88 cm-1 in their Co(II), Ni(II), Cu(II) & Zn(II) complexes. This suggests the participation of azomethine nitrogen in coordination12 with the metals Cobalt (II), Nickel (II), Copper (II) and Zinc (II). The above coordination can be further corroborated by the emergence of a new band in the order of 509.84-539.87 cm-1 in the complexes corresponding to Metal-Nitrogen bond 13. (Fig. S1-S5).
1H-NMR spectrum
In the Schiff base NDBDP, a multiplet is observed in the range from δ 6.55 ppm – δ 7.90 ppm, recommending the presence of aromatic protons14 in the Schiff base. The phenolic proton in the para position of the azomethine 15 group appeared at δ10.49 ppm. (Fig. S6).
13C NMR spectrum
The 13 C spectrum exhibits a band at δ 150.19 ppm, indicates the presence of phenolic 16 carbon. The azomethine 17 carbon is evidenced by the band at δ163 .79 ppm. The aromatic 18 nature of the compound is evidenced by the appearance of bands in the range of δ 115.51 ppm – δ 135.48 ppm . (Fig. S7).
Mass Spectral Studies
In the mass spectrum of the Schiff base NDBDP, the peak that appeared at 367.2464 correlates well with the mass 366.44, calculated for the molecular formula C24H18N2O2 proposed19 to the same. (Fig. S8).
UV-Visible Spectral Studies
The UV-Visible spectrum Schiff base NDBDP shows three bands. The bands at 261.30 nm & 279.90 nm are due to the π →π* transition of the aromatic ring 20, and that observed at 343 nm corresponds to n→π* transition occurring in the azomethine group 21.
The UV-Visible spectrum of the Cobalt (II) complex exhibits spin-allowed transition at 424 nm, and the magnetic moment of 4.63 BM supports the octahedral 22 arrangement around the Cobalt (II) ion. In the Nickel (II) complex the band at 413 nm, can be allocated to the 1A1→1B1 and 1A1→1E1 transitions 23, indicating square planar arrangement around Nickel (II) which is in diamagnetic stable 24. In the Copper (II) complex, a band appears at 797 nm which may be designated to 2B1g→ 2Eg, 2B1g→ 2B2g and 2B1g→ 2A1g transitions 25. The magnetic moment of the Copper (II) metal complex is 1.56 BM, indicates the square planar geometry around 26 Copper (II). The Zinc (II) complex indicates a band at 331 nm, which is attributed 27 to L →M (charge transfer) transition, confirming the square planar arrangement in the Zinc (II) complex and also its diamagnetic nature 28. (Fig. S9-S13).
EPR Spectrum
The ‘g’ value calculated from the EPR determines the ground state. The presence of unpaired electron in dx2– y2 orbital lead to 2B1g as the ground state for which g || > g⊥. For the copper complex, g|| is greater than g⊥, indicating the presence of unpaired electron in dx 2– y 2 orbital 29, leading to square planar geometry resulting from Jahn-teller effect (Fig .1).
Figure 1: EPR Spectrum of Copper Complex |
Metal Estimation Studies
The pyrolitic method is used for cobalt (II) ion estimation. The titrimetric method is followed to determine the quantity of Nickel (II) and Zinc (II) ions, and the Copper (II) ions is ascertained by the colorimetric method. All results comply well with the structures proposed for complexes 30. (Table1).
Table 1: Metal estimation percentage of complexes
Name of the complex |
Calculated (⁒) |
Experimental (⁒) |
[Co(NDBDP)2].H2O [Ni(NDBDP)2] [Cu(NDBDP)2] [Zn(NDBDP)2] |
7.28 7.41 7.98 8.19 |
7.28 7.30 7.27 8.13 |
Conductance Measurement
The electrical conductivity of all the synthesized complexes is determined in DMSO medium (10-3 M). Their molar conductance values 31 are found to be present from 17 ohm-1 cm2 mol-1 to 81 ohm-1cm2 mol-1 which authenticates the neutral nature of the complexes.
Thermal Analysis
In the thermal gravimetric analysis of the cobalt complex, the loss of weight occurred between 101 °C – 194 °C (observed 4.42%, calculated 4.35%) and is correlated to the elimination of two molecules 32 of water coordinated to Co (II) ions. The weight loss corresponding to two moles of ligand observed in the range of 194°C – 470 °C evidences the coordination of two molecules of Schiff base to the Co(II) ions.In the case of the copper complex, the thermal analysis resulted in the first weight loss noticed in the temperature range 105°C – 276°C (observed 46.36%, calculated 46.01%) due to the decomposition of one ligand moiety. The second weight loss occurs in the temperature ranging from 277 °C – 419 °C (observed 46.01, calculated 46.50&) corresponds to the disintegration of the ligand moiety 33 confirming the formation of 1:2 metal to ligand complex. After this weight loss, the complex reached constant mass, indicating its dissipation into analog metal oxides. The thermal analysis data are presented in (Fig .2a & Fig .2b). The suggested structure of the complexes is presented in Fig. 3a & Fig. 3b.
Figure 2a: TGA/DTA curve of Co Complex |
Figure 2b: curve of Cu Complex TGA/DTA |
Figure 3: Structure of the complexes |
DFT Studies
Density functional theory (DFT) calculation studies were executed using the GAUSSIAN09W program package using B3LYP level with 6-31G(d,p) as the basis set. The optimized structure of the Schiff base was visualized with the help of the GAUSSVIEW 6.0 molecular visualization program.
Figure 4a: Optimized Structure of NDBDP |
Figure 4b: Optimized structure of NDBDP with bond length and bond order |
Mulliken Charge Analysis
The atomic charge distribution of various atoms present in the Schiff base is obtained by Mulliken population analysis. The Mulliken, charges of the Schiff base NDBDP lie between -0.553 and 0.553. The high negative charge is mainly localized on azomethine nitrogen and phenolic OH groups. This confirms the coordination sites of the Schiff base. The different color represents Mulliken charge transfer. Mulliken charge population analysis authenticates the intermolecular charge transfer process.
Figure 4c: Mulliken charge transfer of NDBDP |
Frontier Molecular Orbitals
The energy gap between HOMO (-0.18608 a.u) and LUMO (-0.05715 a.u) is found to be 0.12893 a.u (3.5084 eV). The HOMO and LUMO energy gap authenticate intramolecular charge transfer interactions. The smallest HOMO – LUMO gap confirms the softness and reactivity of the Schiff base.34 Energy gap between HOMO-LUMO determines reactivity of the molecule.35
Figure 5: HOMO – LUMO Energy gap of NDBDP |
Molecular Electrostatic Potential
The electronegative site (preferred electrophilic attack) in the MEP diagram is indicated in red color. The counter diagrams show the movement of electrons in the Schiff bases. The red region surrounding azomethine group and phenolic group in MEP proves the reactive sites in Schiff base. The contour of the Schiff base was mapped with electrostatic potential, absolute density, HOMO and LUMO.
Figure 6a: Molecular surface of NDBDP |
Figure 6b: Contour maps of NDBDP |
Table 2: Vibrational frequencies of different bonds present in the Schiff base NDBDP DFT / Experimental
Name of the bond |
Vibrational Frequency |
|
DFT |
IR Spectrum (Experimental) |
|
ν (O-H) ν (C=N) ν (C=C) ν (C-O) ν (C-H) |
3412 1625 1592 1392 1248 818 759 |
3415 1647 1514 1444 1242 830 761 |
Application Studies
Redox Property
The cobalt, copper and zinc complexes, each one exhibit two reduction peaks. The voltammogram of the nickel complex exhibits well denoted redox process. The oxidation and reduction peaks of each complex are given in Table 3. The reduction process is found to be of quasi-reversible process and is all one electron processes 36.The Cyclic voltammograms are given in Fig. 7a to 7d. The difference between forward and reverse peak potentials observed in all the complexes are all greater than 120 mV, indicating that the redox process is metal centred one electron quasi reversible.37
Table 3: Oxidation and Reduction Peaks of Complexes
Name of the Complex |
Oxidation Peak (V) |
Reduction Peak (V) |
(NDBDP)2 -Co
(NDBDP)2 -Ni (NDBDP)2 -Cu
(NDBDP)2 -Zn |
-1.2250 0.0155 0.4142 -1.2083 0.3331 -1.3316 -0.1583 |
-0.9207 -0.0444 -0.5697 -1.0139 0.8329 1.0250 -0.0188 |
Figure 7a: Cyclic voltammogram of Co Complex |
Figure 7b: Cyclic voltammogram of Ni Complex |
Figure 7c: Cyclic voltammogram of Cu Complex |
Figure 7d: Cyclic voltammogram of Zn Complex |
Antimicrobial Activity
The disc diffusion technique is used for scrutinizing the antimicrobial activities of all the compounds. Bacterial pathogens Staphylococcus aureus & Klebsiella pneumonia, and fungal pathogens Aspergillus niger & Candida albicans were taken for the study. Gentamicin and Amphotericin B were used as the positive control. The activities of all the compounds were carried out in a DMSO medium. Considering the bacterial pathogen staphylococcus aures moderate activity is shown by all the compounds. While with Klebsiella pneumonia, the Schiff base ligand shows maximum activity, which is even higher than that of the standard. In the case of a fungal pathogen namely Candida albicans, tremendous activity is observed with both the Schiff base and the Cu(II) complex. (NDBDP)2 – Cu complex is found to have 29% higher activity than the standard drug Amphotericin B. The zone of inhibition values and images relating to biological activity are shown in Table 4 & Fig. 8.
Figure 8: Antimicrobial activities of the Schiff base and their complexes |
Table 4: Antimicrobial activities of the Schiff base and their complexes
S.No |
Organism |
Zone of inhibition (mm) |
|||||
NDBDP |
[Co(NDBDP)2] |
[Ni(NDBDP)2] |
[Cu(NDBDP)2] |
[Zn(NDBDP)2] |
Control |
||
1 2 3 4 |
Staphylococcs aureus Klebsiella pneumonia Aspergillus niger Candida albicans |
14.5 18.5 12.5 18.5 |
13.5 12.5 7.5 12.5 |
12.5 13.5 11.5 14.5 |
12.5 9.5 10.25 22.5 |
14.5 14.5 13.5 15.5 |
17.5 18.25 16.5 17.5 |
Minimum Inhibitory Concentration
The outcome of biological analyses unfurl the fact that the copper complex has more excellent activity towards candida albicans than other compounds and organisms studied. Consequently, the copper complex is analysed for MIC studies. The results indicate that the copper complex is sensitive towards candida albicans even at 0.9 μg/ml. Table 5 & Fig. 9 shown the results.
Table 5: MIC Of Copper Complex
S. No |
Tested sample concentration (μg/ml) |
Mean value |
1 2 3 4 5 6 7 8 9 10 11 |
Control 500 250 125 62.5 31.25 15.6 7.8 3.9 1.9 0.9 |
100 87.34544 68.45567 56.06419 39.22652 33.84636 29.22915 25.49329 22.82294 19.41594 16.96922 |
Figure 9: MIC of Cu (II) Complex |
Antioxidant Activity
The order of antioxidant activity exhibited by the Schiff base and its complexes was Copper (II) > Cobalt (II) > Schiff base > Zinc (II) > Nickel (II). The potential of the samples to infringement the free radical sequence by donation of a hydrogen atom 38 clearly explains the order.
Figure 10: Anti-oxidant Activity of Schiff base and its Complexes |
Anti-inflammatory Activity
The inhibition percentage of albumin denaturation 39 is maximum in the concentration of 500µg/ml in the case of Schiff base as well as Co & Cu complexes. The order of activity is Schiff base > Co complex > Cu complex.
Figure 11: Anti-inflammatory Activity of Schiff base, Cobalt & Copper (II) Complexes |
Anticancer Activity
The copper complex is scrutinized for its anticancer activity by applying on MCF-7 cell line through MTT method. Fig.12 and Table 6 explain the % of cell sustainability in differently concentrated solutions. Comparing the IC 50 value of the complex with that of cisplatin, it is very clear that the copper complex has a moderate cytotoxic effect.
Table 6: % Of Cell Sustainability
Concentration (μg/ml) |
Cell Viability (%) |
Control 500 400 300 200 100 80 60 40 20 10 |
100 13.50522 15.77655 20.44199 25.29159 34.19276 40.88398 50.58318 61.32597 70.53407 82.93432 |
Figure 12: Anticancer Activity of Copper (II) Complex |
Conclusion
A new Schiff base NDBDP is synthesized and it is complexated with Co(II), Ni(II), Cu(II) and Zn(II) metals. From spectral & analytical data, the formation of a 1:2 metal-ligand complex is confirmed. The neutral nature of the complexes is proved by their low conductance values. The geometry of the complexes is determined from analytical and spectral studies. Except for the Co (II) complex, which is proposed octahedral geometry, all other three complexes are proposed square planar geometry. The catalytic application of complexes is revealed by their notable redox property. The Mulliken charge population analysis authenticated the intermolecular charge transfer process. The Schiff base as well as its complexes are established as stupendously bio-potent towards bacterial and fungal pathogens. The Cu (II) complex exhibits greater antioxidant potential than the free Schiff base. The results about anti-inflammatory activity of the Schiff base and its complexes divulge the higher anti-inflammatory activity of Schiff base than its Co (II) and Cu (II) complexes. [Cu(NDBDP)2] exhibits moderate cytotoxic effect over MCF-7 cells.
Acknowledgment
The authors would like to render their sincere gratitude to the Managing Trustee, the Secretary, the Principal and faculty members of the Chemistry Department, Seethalakshmi Ramaswami College, Tiruchirappalli 620002, Tamil Nadu, India for rendering laboratory facilities and guidance. The authors are also greatful to the Director, SAIF, IIT Madras, Chennai, SAIF (Kochin), Archbishop Casimir Instrumentation Centre (ACIC, St. Joseph’s College), Trichy, CARISM (SASTRA Deemed University) and Trichy Research Institute of Biotechnology (P) Ltd, Tiruchirappalli for offering analytical assistance.
Conflict of Interest
The authors declare no competing conflicts of interest to this work.
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