ISSN : 0970 - 020X, ONLINE ISSN : 2231-5039
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Characterization, Biological Activity and DNA Studies of Atomexetine and Ortho Hydroxy Benzaldehyde Imine Metal Complexes

G. S. S. Anjaneya Vasavi1 and J. Sreeramulu2

1Department of Chemistry, RGM College of Engineering and Technology, Nandyal, Andhra Pradesh, India

2Department of Chemistry, S.K University, Anantapuramu, Andhra Pradesh, India

Corresponding Author E-mail: vasavi.sunny@gmail.com

DOI : http://dx.doi.org/10.13005/ojc/360331

Article Publishing History
Article Received on : 26-05-2020
Article Accepted on : 22 Jun 2020
Article Published : 29 Jun 2020
Article Metrics
ABSTRACT:

The rapid increasing applications and anti-bacterial and anti hyperactive properties of different drug the author have synthesized Imine complexes of Atomexetine with O-hydroxy Benzaldehyde. These were depicted with various techniques via Elemental Analysis, UV, FT-IR, NMR, ESR, VSM, Conductivity and TG-DTA. These ligands and metal complexes were also screened for Biological activity and DNA Studies.

KEYWORDS:

Atomexetine; Biological Activity: Copper Chloride; Ruthenium Chloride

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Vasavi G. S. S. A, Sreeramulu J. Characterization, Biological Activity and DNA Studies of Atomexetine and Ortho Hydroxy Benzaldehyde Imine Metal Complexes. Orient J Chem 2020;36(3).


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Vasavi G. S. S. A, Sreeramulu J. Characterization, Biological Activity and DNA Studies of Atomexetine and Ortho Hydroxy Benzaldehyde Imine Metal Complexes. Orient J Chem 2020;36(3). Available from: https://bit.ly/388XAYF


Introduction

Imines are the condensed products of Carbonyl compounds and Amines.1 These are also known as Schiff Bases. The Scientist Hugo Schiff was introduced in 1864.2 Imines show a unique property in the participation of covalent bond with transition metal ions, since the easy formation of ligands act as intermediates for the formation of complexes with transition metal ions. Imine complexes perform biological activities like anti inflammatory, anti fungal, anti bacterial, anti viral, anti diabetic, anti cancer and in pharmaceuticals etc.3-9 Biological activity of the Ligands were recorded by the presence of >C=N moiety of the Schiff bases. These are also having uncountable appliances in technical fields like automobiles, electro plating, printing technology, textile and detergents.10-11

The author has reported characterization, biological activity and DNA studies of the ligands and their metal complexes. The synthesis of Imine metal complexes has been carried out by conventional method and characterization with various techniques like FT-IR, H1-NMR, ESR, UV-Vis and Conductometry. Thermal stability of the complexes was identified by TG-DTA with various temperatures. Biological activity of Imines and their Cu and Ru complexes was performed in in-vitro conditions and DNA binding mode with UV-Vis Spectroscopic technique.

Materials and Methods

Atomexetine (AT), O-hydroxy Benzaldehyde (OHB), methanol, DMF, chlorides of Copper and Ruthenium.

Instrumentation

IR Spectral data with  KBr Pellets, H1-NMR Spectral data  with BRUKER 400MHZ SUPERCON Spectrometer,  ESR Spectral data with Bruker ESP 300E spectrometer, UV-Vis Spectral data  with SchimadzuUV-1800 model Spectrometer, XRD on Panalytical X’pert3 difractometer, conductivity measurements with digital conductivity meter DCM-900, VSM with  EG and G-155 magnetometer were recorded.

Synthesis of OHB-AT Ligand

The equal concentration of AT and OHB was dissolved separately, this mixture was heated for 2-hours by adding few drops of Conc. Hcl, pink colored solution was obtained and this was cooled to room temperature. Then pink color precipitate was obtained. These crystals were washed with methanol and dried in micro wave. The percentage yield of ligand was 80.

Scheme 1: Synthesis of OHB-AT Ligand

Scheme 1: Synthesis of OHB-AT Ligand

Click here to View Scheme

Synthesis of OHBAT-Cu(II) & Ru(III) metal complexes

The complexes were prepared by mixing 1:2 ratio of an aqueous solution of metal ions with the methanolic solution of Imine separately and stirred with magnetic stirrer for proper mixing of contents. Then the contents in the flask were reflexed for six hours and kept in ice bath for cooling, bluish green color sharp needle like crystals were obtained. These were washed and recrystallized with Methanol. The yield of Copper and Ruthenium complexes was 75% and 78%.

Results and Discussions

The main purpose of the present work is to study the characterization of metal complexes with various techniques, Biological activity in in-vitro conditions with different micro-organisms and DNA studies on UV-Vis Spectrophotometer.

IR Spectral Data

The nature of Imine metal complexes were identified by obtaining strong band at 1627 cm-1 indicated the development of Imine group, which on complexing with the metals viz. Cu (II) and Ru (III) the bands appeared at 1605 cm-1 and 1622 cm-1 indicated the coordination between Imine group of nitrogen with electron deficient metal ions because of decreased electron density on Nitrogen atom.12,13 The another strong bands at 420 cm-1 and 429 cm-1 for Copper and Ruthenium expressed  coordination between metal and ligand.14,15 IR data of the ligand and complexes were represented in the table 1

Table 1: IR Spectral data of the ligand and its complexes

Compound

ν OH

Water

ν OH

Phenolic

ν  C=N

ν  M-O

ν  M-N

OHBAT

3363

1627

OHBAT-Cu

3304

1605

620

420

OHBAT-Ru

3413

1622

649

429

NMR Spectral Data

A singlet at 5.6ppm revealed aromatic –OH protons of OHB, this was absent in complex given the coordination between Oxygen moiety of OHB and metal ions of Cu (II) and Ru (III). A singlet at 6.26ppm specified the presence of Imine group of ligand,16 this was shifted to 7.6ppm and 7.26ppm by the coordination of ligand with metal ions. Another singlet at 4.1ppm and 4.65ppm appeared only by the coordination of water molecules with metal ions. NMR data of the ligand and complexes were represented in the table 2

Table 2: NMR spectral data of OHBAT and its metal complexes

S.No

Compound

H-C=N

Ar-H

OH-Phenilic

OH-H2O

-CH3

1

OHBAT

6.26

6.7-7.3

5.6

3.4

2

OHBAT-Cu

7.2

7.4-7.9

4.1

3.7

3

OHBAT-Ru

7.26

7.3-7.7

4.65

3.3

 

ESR Spectral Data

The value of G is >4 shows mononuclear nature of complex. This value can be calculated as,

G = [g‖ – 2.0023 / g┴ – 2.0023]

α2 value of Copper and Ruthenium complexes(0.4518 and 0.4794) specified the covalent nature of complexes. The values of g‖ > gave> g┴ values were greater than 2.0023 said that unpaired electrons of dx2-y2 and dz2 orbital is delocalized for Cu and Ru ions respectively17. ESR spectral data of the complexes were represented table in 3.

Table 3: ESR Spectral data of OHBAT-Cu and OHBAT-Ru

Parameters

OHBAT-Cu

OHBAT-Ru

g‖

2.5864

2.6885

g┴

2.2038

2.3698

gave

2.3313

2.4968

G

4.327

4.5138

A‖*

0.00869

0.00981

A┴*

0.0097

0.0168

Aave

0.0099

0.0126

K‖

0.0762

0.0865

K┴

0.0848

0.0896

P*

0.0336

0.0418

α2

0.2798

0.4198

 

UV-VIS Spectral Data

The transition of ligand was 277nm, which on complexation with Cu (II) and Ru (III) metal complexes change in transitions at 289nm and 306nm signified the charge transfer transition from L→M.18 UV-Vis Spectral data was represented in the table 4.

Table 4: UV-Vis Spectral of OHBAT and ITS Cu (II) and Ru (III) Metal complexes

S.No

Compound

λmax

1

OHBAT

277

2

OHBAT-Cu

289

3

OHBAT-Ru

306

 

XRD of OHBAT-Cu and OHBAT-Ru Metal Complexes

The diffractograms, calculated miller indices (h k l) values, ‘2Ɵ’and‘d’ values were represented in the table5 suggested a good agreement between‘2Ɵ’ and‘d’ values. 2Ɵ values recommended poor crystallinity of the complexes.19 The miller indices values are calculated as, Nλ =2d sinƟ

One of the value of

2Ɵ = 5.2805

Ɵ = 2.64025

SinƟ = 0.046064

h k l =  1 1 1

XRD values of the complexes were represented in the tables 5 – 6.

Table 5: XRD studies of OHBAT-Cu metal complex

S.No

d exp

d cal

2Ɵ  exp

2Ɵ cal

h  k  l

1

0.0354

0.0349

5.2805

5.2801

1  1  1

2

0.03917

0.03912

5.8303

5.8299

1  1  1

3

0.04428

0.04422

6.5921

6.5915

1  1  1

4

0.04925

0.04919

7.3326

7.3321

2  1  1

5

0.05915

0.05910

8.8085

8.8081

2  2  1

6

0.0623

0.0619

9.2791

9.2785

2  2  1

7

0.0965

0.0959

14.3999

14.3994

5  4  4

8

0.1039

0.1033

15.5905

15.5901

5  5  2

9

0.1088

0.1081

16.2419

16.2414

5  5  3

10

0.1255

0.1250

18.7663

18.7659

6  6  3

11

0.1311

0.1308

19.6003

19.6000

6  6  4

12

0.1466

0.1459

21.9204

21.9199

6  6  6

13

0.1800

0.1796

27.0421

27.0415

9  8  4

14

0.1891

0.1886

28.4342

28.4339

9  9  4

15

0.1948

0.1944

29.2495

29.2489

9  9  5

16

0.2165

0.2161

32.6565

32.6559

10  10  6

17

0.2308

0.2301

34.8814

34.8809

11 10  7

18

0.2582

0.2579

39.1821

39.1816

12  11  8

19

0.2882

0.2876

42.9935

42.9931

12  11  10

20

0.2929

0.2924

44.7026

44.7021

12  12  12

21

0.2982

0.2976

45.5550

45.5546

13  13  10

22

0.3252

0.3249

49.9612

49.9606

14  14  12

23

0.3742

0.3737

58.1390

58.1384

16  16  14

24

0.4059

0.4055

63.5485

63.5481

17  17  16

25

0.4693

0.4688

75.0662

75.0658

20  19  19

26

0.5132

0.5129

83.560

83.555

21  21  20

Table 6: XRD studies of OHBAT-Ru metal complex

S.No

d exp

d cal

2Ɵ  exp

2Ɵ cal

h  k  l

1

0.0407

0.0401

6.0709

6.0701

1  1  1

2

0.0490

0.0485

7.2553

7.2549

1  1  1

3

0.0563

0.0558

8.3951

8.3945

2  1  1

4

0.0634

0.0631

9.4552

9.4546

2  2  1

5

0.0855

0.0851

12.7476

12.7470

4  4  2

6

0.0934

0.0929

13.9398

13.9392

5  4  1

7

0.1246

0.1241

18.6317

18.6312

6  5  4

8

0.1306

0.1299

19.5272

19.5266

6  6  4

9

0.1328

0.1321

19.9280

19.9274

7  6  1

Analysis of TG-DTA

By observing modifications at different temperature ranges one can easily explain thermal stability of the complexes. The temp ranges between 1100C-222.100C and 2150C-2800C specified the loss of two water molecules at the first level,20 the second level at 261.030C and 4500C specified the formation of stable intermediate peaks as the results of decomposition at the temperature range of 8180C and 6000C. At high temp metallic oxides formation takes by the exothermic process. Thermal data of Cu (II) and Ru (III) metal complexes were represented in the table 7.

Table 7: Thermal Data of OHBAT-Cu and OHBAT-Ru Metal Complexes

Complex

Molecular weight (grams)

Temperature range in 0c

Probable assignment

Mass loss (%)

Total mass loss (%)

OHBAT-Cu

894.68

110 -222.10

261.03-818.34

Above 818.34

Loss of two H2O molecules

Loss of two ligand molecules

Formation of CuO

4.5

25.53

40.35

70.22

OHBAT-Ru

932.41

215-280

450-600

Above 600

Loss of two H2O molecules

Loss of two ligand molecules

Formation of CuO

5.35

27.35

55.63

88.33

Conductometry

Molar Conductivity value of the complexes at 58 and 60 Ohm-1cm2mol-1 for Cu(II) and Ru(III) specified non electrolytic in nature.21 Molar conductance values of the complexes were represented in the table 8.

Table 8: Conductivity values of OHBAT-Cu (II) and OHBAT-Ru(III) metal  complexes

S.No

complex

Conductance

Ohm-1cm2mol-1

1

 OHBAT-Cu

58

2

OHBAT-Ru

60

VSM Analysis

The magnetic momentum values of OHBAT-Cu and OHBAT-Ru complexes at 4.28 and 5.56 BM specified octahedral geometry22, 23 of the complexes due to the presence of lone pair of electrons in d-orbital of the metal ions. The magnetic susceptibility values of OHBAT-Cu and OHBAT-Ru complexes were represented in the table 9.

Table 9: Magnetic momentum values of OHBAT-Cu and OHBAT-Ru complexes

S.No

complex

Magnetic momentum (BM)

      1

OHBAT-Cu

4.28

2

OHBAT-Ru

5.56

 

Biological Studies

Biological studies of the ligands and complexes were performed in in-vitro conditions; represented biological activity of Imines was less than their corresponding metal complexes because of the reduced electron density of metal ions by the transfer of charge, according to Chelating theory.24 The biological activity values of Imines and their metal complexes were represented in the table 10.

Table 10: Biological studies of the metal complexes of Copper & Ruthenium metal ions

Compound

E-Coli

Klebsiella

Bacillus

OHBAT

9

11

14

OHBAT-Cu

10

13

15

OHBAT-Ru

11

14

16

 

DNA binding mode of the complexes

DNA binding activity of the complexes was performed with di sodium salt of calf DNA. The spectrum was performed in the absence and presence of CT-DNA. In the presence of CT-DNA the complexes conveyed hypochromic shift because of the presence of chromophores of the ligand. The quantitative comparisons of binding parameters from the following equation

[DNA]/ (εa– εf) = [DNA] / (εb– εf) + 1 Kbb– εf)

The binding constants of the complexes were represented in the table 11.

Table 11: DNA Activity of OHBAT-Cu and OHBAT-Ru Metal Complexes

S.No

Complex

        λmax   nm

Free            Bound

∆λ nm

 H%

Kb(M-1)

3

OHBAT-Cu

305

311

6

6.35

3.94 x 106

4

OHBAT-Ru

313

317

6

6.29

3.28 x 106

Conclusions

In the present article author has reported characterization, biological activity and DNA studies of the metal complexes of Cu (II) and Ru (III) metal ions. The characterization reports suggested, the complex was mono nuclear with molecular formula of [M (L) 2]. The stoichiometry of the complex was 1:2 ratios and proposed geometry of the complexes was octahedral. The complexes were exhibit more biological activity than their corresponding ligands.

Acnowledgement

I would like to express my deepest appreciation to my Professor J. Sreeramulu garu department of chemistry, SK University, Anantapuramu for his continuous support in my research area.

I would like thanks to RGM college of Engineering and technology for encouraging in the area of research.

Conflicts of Interest

The author has no conflicts regarding publication of this paper.

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