Synthesis, characterization and antimicrobial activity of diorganotin(IV) derivatives of some bioactive bifunctional tridentate Schiff base ligands

Pooja Bhatra; Jyoti Sharma; Ram Avatar Sharma; Yashpal Singh

doi:10.1515/mgmc-2015-0022

Article Publicly Available

Synthesis, characterization and antimicrobial activity of diorganotin(IV) derivatives of some bioactive bifunctional tridentate Schiff base ligands

Pooja Bhatra , Jyoti Sharma , Ram Avatar Sharma and Yashpal Singh

Published/Copyright: January 22, 2016

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From the journal Main Group Metal Chemistry Volume 39 Issue 1-2

Abstract

Some new organotin(IV) complexes of the type R₂Sn[OC(R′):CH(CH₃)C:NR″O] (R=CH₃, C₄H₉, C₆H₅; R′=CH₃, C₆H₅; and R″=(CH₂)₂, (CH₂)₃) have been synthesized by the reactions of diorganotin dichloride with the sodium salt of the corresponding bifunctional tridentate Schiff base ligands in unimolar ratio in refluxing tetrahydrofuran (THF). All these compounds have been characterized by elemental analyses, and their probable structures, in which the central tin atom is pentacoordinated, have been proposed on the basis of infrared (IR) and ¹H, ¹³C and ¹¹⁹Sn NMR and fast atom bombardment mass spectroscopic studies. The ligands, metal precursors and their corresponding diorganotin complexes have also been screened for antimicrobial activities.

Keywords: antimicrobial activities; diorganotin(IV) Schiff base derivatives; FAB mass spectrometry; NMR spectroscopy; pentacoordinated tin

Introduction

Organotin(IV) complexes have been the subject of interest for some time because of their biomedical and commercial applications (Pellerito and Nagy, 2002). The syntheses of organotin(IV) complexes derived from Schiff bases have been extensively studied in the past decade (Dey et al., 2009; Sedaghat et al., 2012a,b,c). In recent years, interest is growing widely as a result of their antimicrobial, antiviral and antitumor activities (Joshi et al., 2005; Singh et al., 2009; Nath et al., 2013). Schiff base complexes also provide synthetic models for active sites in biological systems (Baul et al., 2008) and offer opportunities for enhancing solubility and stability of their metal complexes (Borisova et al., 2007). During the last decade, metal complexes of group 14 have made a major contribution with their antimicrobial activity, and it is well reported that the activity of Schiff bases are often enhanced due to chelation with metal (Sharma et al., 2007; Singh et al., 2011).

In view of the above facts, we have synthesized and characterized some new diorganotin(IV) complexes with Schiff bases derived from β-diketones and amino alcohols. These compounds have been screened for antimicrobial activities. The antimicrobial activities of these tin compounds have been compared with the corresponding free Schiff bases and metal precursors.

Results and discussion

Syntheses of organotin(IV) derivatives

Ligands have been synthesized by the condensation reaction of β-diketones and selected amino alcohols in unimolar ratio. These ligands may exist in various forms (Scheme 1). The structure (C) seems to be more likely in view of the spectroscopic studies and the single crystal X-ray diffraction analysis of organotin compounds of similar ligands reported in the literature (Dey et al., 2009).

Scheme 1:

Syntheses of bifunctional tridentate Schiff bases (1a–1d) and diorganotin derivatives (2a–2l) and schematic drawings of the different forms of ligands (A–D).

The reactions of R₂SnCl₂ with the sodium salt of Schiff base ligands (synthesized by the reaction of Schiff bases and freshly prepared sodium methoxide) in 1:1 molar ratio in refluxing tetrahydrofuran (THF) yield organotin complexes.

Spectroscopic studies

Infrared spectra

In the infrared (IR) spectra of these derivatives, disappearance of the broad band indicates the deprotonation of -OH group, observed in the spectra of parent ligands at 3300–3600 cm^-1 and assigned to aminol OH. This is further supported by the appearance of a new band at 512–536 cm^-1 due to ν_(Sn-O) stretching vibrations. In the IR spectra of all complexes, the azomethine ν_(C=N) band appears at 1571–1602 cm^-1 (appeared at 1617–1625 cm^-1 in free ligands). Considerable shifts to the lower wave number in its position may be due to the involvement of >C=N group nitrogen in coordination with the tin atom. The appearance of a new band in the IR spectra of these complexes in the region 441–448cm^-1 and assigned to ν_(Sn-N) supports the formation of a Sn-N bond (Sedaghat et al., 2011).

¹H NMR spectra

In the ¹H NMR spectra (Table 1) of ligand enolic and aminol, -OH signals were observed at δ 11.3–12.2 and δ 3.4–4.4, respectively. Absence of these signals in the spectra of diorganotin(IV) derivatives reveals the deprotonation and bonding of these groups with tin atom. Aromatic protons appeared as a multiplet in the region δ 7.9–7.3 in the spectra of ligands as well as their tin complexes. ¹H NMR signals due to butyl group attached to tin appeared in the region δ 1.9–1.2 (2e–2h). The singlet for CH₃–Sn appeared in the region δ 0.57–1.9, and ²J(¹¹⁹Sn-¹H) value is observed in the range 69.4–80.2 Hz for 2a–2d derivatives. These values are found larger than for non-complexed Me₂SnCl₂ (68.7 Hz) (Sedaghat et al., 2011) and found to be in the range of pentacoordinated tin atom (64–79 Hz) (Lockhart et al., 1986) for these dimethyltin(IV) complexes. The ²J(¹¹⁹Sn-¹H) coupling constant value could not be observed for butyl tin(IV) derivatives as these signals are merged with alkyl and phenyl protons of ligand moieties. There is also no ²J(¹¹⁹Sn-¹H) coupling for Sn-Ph moieties as the Ph group does not carry any alpha hydrogen.

Table 1

NMR spectroscopic data (δ) of the Schiff bases 1a–1d (¹H) and the diorganotin(IV) derivatives 2a–2l (¹H, ¹¹⁹Sn).

Compound	R	R′	R″	¹H NMR	¹¹⁹Sn NMR
1a		CH₃	-(CH₂)₂-	5.521(s)-CHCO, 3.284(t)-CH₂O, 3.115(t)-CH₂N, 2.010(s)-CH₃CO, 1.854(s)-CH₃CN
1b		CH₃	-(CH₂)₃-	5.534(s)-CHCO, 3.301(t)-CH₂O, 3.202(t)-CH₂N, 2.035(s)-CH₃CO, 1.915(s)-CH₃CN
1c		C₆H₅	-(CH₂)₂-	7.152–7.741(m)-C₆H₅, 5.539(s)-CHCO, 3.421(t)-CH₂O, 3.315(t)-CH₂N, 1.714(s)-CH₃CN
1d		C₆H₅	-(CH₂)₃-	7.251–7.811(m)-C₆H₅, 5.540(s)-CHCO, 3.654(t)-CH₂O, 3.299(t)-CH₂N, 1.762(s)-CH₃CN
2a	CH₃	CH₃	-(CH₂)₂-	5.544(s)-CHCO, 3.313(t)-CH₂O(J=7.44 Hz), 3.212(t)-CH₂N(J=6.12 Hz), 2.056(s)-CH₃CO, 1.969(s)-CH₃CN, 1.727(s)-CH₃, Sn²J(¹¹⁹Sn-¹H)=69.4 Hz	-140.7
2b	CH₃	CH₃	-(CH₂)₃-	5.582(s)-CHCO, 3.472(t)-CH₂O(J=7.44 Hz), 3.370 (t)-CH₂N(J=7.44 Hz), 3.204(m)-CH₂-CH₂-CH₂-, 1.997(s)-CH₃CO, 1.742(s)-CH₃CN, 1.216(s)-CH₃Sn, ²J(¹¹⁹Sn-¹H)=72.9 Hz	-142.4
2c	CH₃	C₆H₅	-(CH₂)₂-	7.192–7.811(m)-C₆H₅, 5.554(s)-CHCO, 3.714(t)-CH₂O(J=7.8 Hz), 3.352(t)-CH₂N(J=6.5 Hz), 1.777(s)-CH₃CN, 0.774(s)-CH₃Sn, ²J(¹¹⁹Sn-¹)=77.8 Hz	-149.2
2d	CH₃	C₆H₅	-(CH₂)₃-	7.312–7.775(m)-C₆H₅, 5.591(s)-CHCO, 3.691(t)-CH₂O(J=7.9 Hz), 3.404(t)-CH₂N(J=6.14 Hz), 3.389(m)-CH₂-CH₂-CH₂-, 1.827(s)-CH₃CN, 1.812(s)-CH₃Sn, ²J(¹¹⁹Sn-¹H)=77.8 Hz	-152.7
2e	C₄H₉	CH₃	-(CH₂)₂-	4.909(s)-CHCO, 3.680(t)-CH₂O(J=7.4 Hz), 3.356(t)-CH₂N(J=7.1 Hz), 1.920(s)-CH₃CO, 1.908(s)-CH₃CN, 1.154–1.749(m)-C₄H₁₀	-179.3
2f	C₄H₉	CH₃	-(CH₂)₃-	4.888(s)-CHCO, 3.316(t)-CH₂O(J=7.44 Hz), 3.003(t) (J=6.78 Hz)-CH₂N, 3.204(m)-CH₂-CH₂-CH₂-, 1.910(s)-CH₃CO, 1.874(s)-CH₃CN, 1.591–1.184(m)-C₄H₁₀	-178.9
2g	C₄H₉	C₆H₅	-(CH₂)₂-	7.336–7.753(m)-C₆H₅, 5.535(s)-CHCO, 3.684(t)-CH₂O(J=9 Hz), 3.332(t)-CH₂N(J=6.8 Hz), 1.969(s)-CH₃CN, 1.290–1.175(m)-C₄H₁₀	-182.3
2h	C₄H₉	C₆H₅	-(CH₂)₃-	7.139–7.656(m)-C₆H₅, 5.134(s)-CHCO, 3.589(t)-CH₂O(J=7.71 Hz), 3.271(t)-CH₂N(J=6.5 Hz), 2.998(m)-CH₂-CH₂-CH₂-, 1.969(s)-CH₃CN, 1.872–1.183(m)-C₄H₁₀	-185.5
2i	C₆H₅	CH₃	-(CH₂)₂-	7.569–7.372(m)-C₆H₅, 5.482(s)-CHCO, 3.523(t)-CH₂O(J=7.41 Hz), 3.295(t)-CH₂N(J=6.66 Hz), 2.001(s)-CH₃CO, 1.927(s)-CH₃CN	-254.8
2j	C₆H₅	CH₃	-(CH₂)₃-	7.754–7.275(m)-C₆H₅, 5.561(s)-CHCO, 3.648(t)-CH₂O(J=7.9 Hz),3.339(t)-CH₂N(J=7.1 Hz), 3.323(m)-CH₂-CH₂-CH₂-, 1.951(s)-CH₃CO, 1.799(s)-CH₃CN	-255.3
2k	C₆H₅	C₆H₅	-(CH₂)₂-	7.856–7.305(m)-C₆H₅, 5.515(s)-CHCO, 3.515(t)-CH₂O(J=7.81 Hz),3.341(t)-CH₂N(J=6.44 Hz), 1.774 (s)-CH₃CN	-269.4
2l	C₆H₅	C₆H₅	-(CH₂)₃-	7.671–7.293(m)-C₆H₅, 5.392(s)-CHCO, 3.697(t)-CH₂O(J=9 Hz),3.317(t)-CH₂N(J=7.03 Hz), 3.235(m)-CH₂-CH₂-CH₂-, 1.704(s)-CH₃CN	-271.1

Substitution of ²J(¹¹⁹Sn-¹H) coupling constant values (2a–2d) in the Lockhart-Manders equation gives the value 125.2°–131.1° for the Me-Sn-Me angle. The observed values for Me-Sn-Me angle further support the pentacoordinated tin (Lockhart et al., 1985) having trigonal bipyramidal geometry in all these derivatives.

¹³C NMR spectra

¹³C NMR spectral data of these derivatives have been summarized in Table 2. The spectra of all these derivatives (2a–2l) exhibit signal for >C-O- enolic group carbon in the range δ 187.5–195.8 in these organotin compounds as well as their corresponding ligands. A small downfield shift is observed in the position of this signal as compared to their corresponding free ligands. Signal for >C=N imine group carbon has been observed in the range δ 162.9–165.9. A downfield shift of ~2–5 ppm has been observed as compared to its position in corresponding free Schiff base ligands. The shifts in the positions of carbon atom adjacent to the imine group nitrogen suggest that nitrogen is involved with tin in these complexes. The signal for CH₂O- group carbon (deprotonated amino alcohol group) appeared in the range of δ 60.7–68.3 having a slight downfield shift (~2 ppm) as compared to their position in free Schiff base moieties. Signals for CH₃-Sn group carbon appeared in the range δ 19.4–20.3 in 2a–2d derivatives. The ¹J(¹¹⁹Sn-¹³C) coupling constant values were found in the range 553–596 Hz for 2a–2d derivatives, which is consistent with pentacoordination range (470–610 Hz) (Lockhart et al., 1985).

Table 2

¹³C NMR spectroscopic data (δ) of some new diorganotin(IV) Schiff base derivatives.

Compound			Phenyl carbon				Alkylene carbon
Compound			C₁ C_1′	C₂ C_2′	C₃ C_3′	C₄ C_4′	Alkylene carbon
1a			–	–	–	–	93.6(=CH-), 62.1(CH₂O), 57.6(CH₂N), 33.3(CH₃CO), 25.8(CH₃CN)
	191.1	162.6	–	–	–	–
1b			–	–	–	–	94.1(=CH-), 61.3(CH₂O), 57.7(CH₂N), 40.5(CH₂), 32.5(CH₃CO), 26.2(CH₃CN)
	193.5	163.4	–	–	–	–
1c			–	–	–	–	94.3(=CH-), 61.7(CH₂O), 58.2(CH₂N), 26.6(CH₃CN)
	188.2	161.7	140.9	135.1	130.5	126.1
1d			–	–	–	–	95.8(=CH-), 62.4(CH₂O), 58.5(CH₂N), 41.2(CH₂), 26.3(CH₃CN)
	187.1	163.8	140.5	135.4	129.4	126.9
2a			–	–	–	–	94.9(=CH-), 62.2(CH₂O), 58.1(CH₂N), 33.9(CH₃CO), 26.4(CH₃CN), 19.4(CH₃Sn), ¹J(¹¹⁹Sn-¹³C)=553 Hz
	194.2	164.2	–	–	–	–
2b			–	–	–	–	96.6(=CH-), 68.3(CH₂O), 51.2(CH₂N), 41.2(CH₂), 31.2(CH₃CO), 24.3(CH₃CN) 20.3(CH₃Sn), ¹J(¹¹⁹Sn-¹³C)=561 Hz
	195.8	165.0	–	–	–	–
2c	189.7	164.3	–140.2	–135.7	–130.1	–126.5	94.7(=CH-), 67.2(CH₂O), 57.7(CH₂N), 28.0(CH₃CN) 19.9(CH₃Sn), ¹J(¹¹⁹Sn-¹³C)=578 Hz
2d			–	–	–	–	92.2(=CH-), 70.1(CH₂O), 59.5(CH₂N), 39.9(CH₂), 26.4(CH₃CN) 19.4(CH₃Sn), ¹J(¹¹⁹Sn-¹³C)=596 Hz
	187.6	165.4	140.4	136.0	129.9	126.8
2e			–	–	–	–	95.7(=CH-), 67.6(CH₂O), 52.4(CH₂N), 33.2(CH₃CO), 27.4,(CH₃CN), 23.1–19.2(C₄H₁₀)
	194.8	164.2	–	–	–	–
2f			–	–	–	–	94.6(=CH-), 62.7(CH₂O), 56.2(CH₂N), 38.9(CH₂), 31.6(CH₃CO), 28.3(CH₃CN), 26.0–17.8(C₄H₁₀)
	194.1	162.9	–	–	–	–
2g			–	–	–	–	94.9(=CH-), 62.0(CH₂O), 51.9(CH₂N), 27.4(CH₃CN), 25.4–19.6(C₄H₁₀)
	187.9	165.8	140.3	135.7	129.8	126.7
2h			–	–	–	–	95.2(=CH-), 60.9(CH₂O), 53.6(CH₂N), 39.8(CH₂), 28.5(CH₃CN) 21.8–15.7(C₄H₁₀)
	194.5	163.8	140.4	136.2	130.1	126.1
2i			139.4	136.6	129.1	125.8	94.2(=CH-), 65.2(CH₂O), 57.2(CH₂N), 35.2(CH₃CO), 27.6(CH₃CN)
	194.2	163.6	–	–	–	–
2j			139.4	135.9	129.5	126.5	92.2(=CH-), 66.3(CH₂O), 59.3(CH₂N), 40.1(CH₂), 32.1(CH₃CO), 27.1(CH₃CN)
	187.5	165.7	–	–	–	–
2k			138.1	135.0	129.1	125.8	95.7(=CH-), 60.7(CH₂O), 53.6(CH₂N), 39.9(CH₂), 24.8(CH₃CN)
	192.9	164.9	139.3	136.8	130.4	126.3
2l			139.2	135.9	128.9	126.2	94.6(=CH-), 64.6(CH₂O), 60.2(CH₂N), 44.5(CH₂), 26.2(CH₃CN)
	193.7	162.9	140.9	137.1	130.3	127.0

C₁, C₂, C₃ and C₄ denote the phenyl carbons of group R. C_1′, C_2′, C_3′ and C_4′ denote the phenyl carbons of group R_′.

¹¹⁹Sn NMR spectra

¹¹⁹Sn NMR spectra of tin complexes exhibit one sharp singlet in the range δ -140.7 to δ -271.1. These chemical shifts are observed at lower frequency as compared to SnMe₂Cl₂ (137 ppm), SnBu₂Cl₂ (122 ppm) and SnPh₂Cl₂ (-32 ppm) (Sedaghat et al., 2012a,b,c) and depict the presence of five coordinated tin atoms in these derivatives.

Fast atom bombardment mass spectra

Fast atom bombardment (FAB) mass spectral data of three diorganotin(IV) derivatives (2a), (2e) and (2i) have been recorded. The spectra reveal the monomeric nature of these compounds, and their fragmentation patterns are being summarized in the Experimental section. The mass peaks indicate the formation of a variety of fragments during the course of decomposition. In these three compounds, molecular ion peaks are observed at m/z 291, 374 and 414, respectively. Base peaks for these compounds are observed at 278 (2a), 361(2e) and 401(2i). In all these three compounds, molecular ion peaks are not observed as base peak and fragmentation initiate in same manner by the loss of ethylenic (=CH) carbon. After the formation of base ion peak in these compounds 2a, 2e and 2i, the decomposition takes place through the fragmentation of Schiff base moiety.

The [R-Sn]⁺ fragment is formed as a final decomposition product in all these three compounds, showing strong R-Sn bonding.

Structural elucidation

In view of the above mentioned spectroscopic data, the following structures having bifunctional tridentate Schiff bases with pentacoordinated tin may be proposed in solution for these diorganotin(IV) derivatives 2a–2l (see drawing in Scheme 1). According to the Bent’s rule, both the R- groups will occupy equatorial positions. Pentacoordination around tin atom (bond angle of 124°–131°) is confirmed by ¹H, ¹³C and ¹¹⁹ Sn NMR spectroscopic data, and the opening of the bond may be explained by the solvent effect.

Antimicrobial activity

Diorganotin derivatives (2a–2l) with their corresponding free Schiff bases (1a–1d) and metal precursors were screened against bacteria (Table 3: Figures S1, S2, S3 and S4) and fungi (Table 4: Figures S5 and S6) to examine their growth inhibitory potential towards the test organisms. Apparently, the complexes are more toxic towards Gram-positive strains (Staphylococcus aureus and Bacillus subtilis) than Gram-negative strains (Escherichia coli and Pseudomonas aeruginosa). The reason probably lies in the difference between the structures of the cell walls. The relatively more complex walls of Gram-negative cells may prevent the diffusion of chemicals into the cytoplasm of the organisms, which may not be the case of Gram-positive cells. The results indicate that the metal chelates have higher activity than the free ligands as well as metal precursors. This increased activity of the metal chelates can be explained by Tweedy’s chelation theory (Tweedy, 1964) and Overtone’s concept. According to Overtone’s concept of cell permeability, the lipid membrane that surrounds the cell favors passage of only lipid-soluble material due to liposolubility, which is an important factor that controls antimicrobial activity. On chelation, the polarity of the metal ions is reduced to a greater extent due to the overlap of the ligand orbital and partial sharing of the positive charge of the metal ion with a donor group. Enhanced activity may be due to the coordination of ligand to tin leading to electron delocalization and therefore increasing the lipophilic character and efficient diffusion of the metal complexes into bacterial cells. It has been observed that a small structural change, such as change of alkyl group present, increases the activity of compounds in the order R=CH₃<C₄H₁₀<C₆H₅ (Sonika and Malhotra, 2011).

Table 3

Antibacterial studies of the ligands and their organotin derivatives (2a–2l).

Compound	Concentration (mg/mL)	Zone size (mm)
Compound	Concentration (mg/mL)	S. aureus	B. subtilis	E. coli	P. aeruginosa
Me₂SnCl₂	2	7	6	6	5
	4	8	9	8	7
Bu₂SnCl₂	2	7	7	5	6
	4	10	10	9	9
Ph₂SnCl₂	2	9	8	8	7
	4	12	11	10	10
LH₂ (1a)	2	6	7	5	7
	4	8	9	7	9
LH₂ (1b)	2	7	8	6	8
	4	10	10	9	10
LH₂ (1c)	2	6	7	6	7
	4	8	12	8	11
LH₂ (1d)	2	7	9	7	9
	4	11	14	10	12
2a	2	11	9	8	7
	4	14	15	13	11
2b	2	13	12	11	10
	4	17	15	16	14
2c	2	10	12	10	9
	4	13	16	13	12
2d	2	14	13	12	8
	4	17	17	16	11
2e	2	12	12	12	9
	4	17	19	13	13
2f	2	15	17	14	12
	4	19	20	18	17
2g	2	13	14	13	10
	4	19	19	17	13
2h	2	16	16	11	12
	4	20	19	14	19
2i	2	14	14	12	13
	4	19	20	15	18
2j	2	17	17	13	15
	4	21	20	19	18
2k	2	15	14	12	14
	4	18	16	18	16
2l	2	17	18	11	13
	4	20	21	16	15

Table 4

Antifungal studies of the ligands and their organotin derivatives (2a–2l).

Compound	Concentration (mg/mL)	Zone size (mm)
Compound	Concentration (mg/mL)	F. oxysporum	T. reesei	P. funiculosum	A. niger
Me₂SnCl₂	2	7	6	6	5
	4	8	9	8	7
Bu₂SnCl₂	2	9	8	7	6
	4	11	12	11	10
Ph₂SnCl₂	2	11	10	9	8
	4	13	12	13	12
LH₂ (1a)	2	6	5	5	6
	4	7	9	8	9
LH₂ (1b)	2	7	8	6	7
	4	9	11	9	10
LH₂ (1c)	2	8	7	7	8
	4	10	11	10	11
LH₂ (1d)	2	7	9	7	8
	4	11	12	12	10
2a	2	8	7	8	9
	4	12	11	10	13
2b	2	10	9	14	13
	4	13	12	16	17
2c	2	11	13	11	14
	4	15	14	15	16
2d	2	12	15	16	17
	4	15	18	20	20
2e	2	11	11	13	14
	4	13	14	17	19
2f	2	13	12	14	17
	4	15	16	18	24
2g	2	16	17	17	17
	4	19	19	21	22
2h	2	18	19	20	18
	4	20	22	23	22
2i	2	12	10	15	16
	4	18	16	21	20
2j	2	13	12	14	18
	4	17	16	19	22
2k	2	14	17	17	19
	4	19	19	21	22
2l	2	15	16	19	20
	4	18	20	24	23

The concentration of a compound is another important factor on which the inhibition growth is affected. At lower concentration (2 mg/mL) growth will be slowed down, while at higher concentration more enzymes will become inhibited, leading to a quicker death of organism.

Conclusion

The organotin(IV) derivatives reported here have been characterized by elemental analyses, IR, NMR and FAB mass spectral data. Schiff bases behave as a bifunctional tridentate moiety. ¹H, ¹³C and ¹¹⁹Sn NMR values support the pentacoordinated tin having distorted trigonal bipyramidal geometry. The metal derivatives were found to be more inhibitory than corresponding Schiff bases in the result of antimicrobial activities, and the activity increases with the concentration and depend on the nature of the group attached to the tin atom.

Experimental

Materials and methods

Solvents were purified and dried by standard procedures. Schiff bases (1a–1d) were prepared by the condensation reactions of β-diketones with appropriate amino alcohols. Dialkyltin dichloride (Aldrich, USA) was distilled prior to use. Tin was estimated (Vogel, 1989) as tin dioxide in these derivatives. Carbon, hydrogen and nitrogen were analyzed on elemental analyzer Elementar Vario EL III.

¹H, ¹³C and ¹¹⁹Sn NMR spectra were recorded in CDCl₃ solution on Bruker FT 400 MHz NMR spectrometer (Brucker coorporation, Billerica, MA, USA). TMS was used as internal reference for ¹H and ¹³C NMR spectra. IR spectra were recorded on 8400 s SHIMADZU FT IR Spectrophotometer (Kyoto, Japan) as nujol mull in KBr disk in the range 4000–400 cm^-1. The FAB mass spectra of three representative compounds were recorded on Jeol-SX 102/Da-600 mass spectrometer (Jeol coorporation, Akishima, Tokyo, Japan).

As the synthetic procedure for all these compounds is the same, for the sake of brevity details of only one compound are given, and the analytical as well as preparative details of the rest of compounds are summarized in Table 5.

Table 5

Synthetic and analytical data of some new diorganotin (IV) Schiff base derivatives (2a–2l).

Compd	Reactants g/(mmol)			NaCl found (calcd.)	Empirical formula (Yield %)	Color, physical state (m.p., °C)	Analyses % found (calcd.)
Compd	R₂SnCl₂	LNa₂	LH₂	NaCl found (calcd.)	Empirical formula (Yield %)	Color, physical state (m.p., °C)	Sn	C	H	N
2a	1.505 (6.84)	1.280 (6.84)	0.98 (6.84)	0.792 (0.803)	C₉H₁₇O₂NSn (83)	Creamish white, solid (155)	40.87 (40.94)	37.11 (37.28)	5.85 (5.90)	4.77 (4.83)
2b	1.439 (6.54)	1.315 (6.54)	1.028 (6.54)	0.753 (0.766)	C₁₀H₁₉O₂NSn (79)	Dark brown, viscous	38.95 (39.05)	39.74 (39.51)	6.21 (6.29)	4.48 (4.60)
2c	1.248 (5.67)	1.413 (5.67)	1.163 (5.67)	0.649 (0.662)	C₁₄H₁₉O₂NSn (78)	Creamish white, solid (162)	33.61 (33.72)	47.53 (47.76)	5.33 (5.44)	3.87 (3.99)
2d	1.195 (5.43)	1.429 (5.43)	1.190 (5.43)	0.627 (0.636)	C₁₅H₂₁O₂NSn (76)	Dark brown, viscous	32.31 (32.43)	48.98 (49.22)	5.61 (5.78)	3.85 (3.83)
2e	1.622 (5.34)	1.00 (5.34)	0.764 (5.34)	0.613 (0.625)	C₁₅H₂₉O₂NSn (82)	Light brown, solid (168)	31.67 (31.73)	48.25 (48.16)	7.91 (7.81)	3.76 (3.74)
2f	1.564 (5.15)	1.036 (5.15)	0.809 (5.15)	0.591 (0.602)	C₁₆H₃₁O₂NSn (81)	Brown, viscous	30.50 (30.58)	49.26 (49.51)	8.11 (8.04)	3.52 (3.60)
2g	1.388 (4.57)	1.139 (4.57)	0.938 (4.57)	0.523 (0.536)	C₂₀H₃₁O₂NSn (78)	Brown, solid (171)	27.07 (27.21)	55.18 (55.07)	7.10 (7.16)	3.11 (3.21)
2h	1.349 (4.44)	1.168 (4.44)	0.973 (4.44)	0.501 (0.519)	C₂₁H₃₃O₂NSn (75)	Brown, viscous	26.15 (26.36)	55.91 (56.02)	7.29 (7.38)	3.16 (3.11)
2i	1.656 (4.81)	0.901 (4.81)	0.689 (4.81)	0.551 (0.564)	C₁₉H₂₁O₂NSn (81)	Creamish white, solid (182)	28.32 (28.67)	55.43 (55.11)	5.13 (5.11)	3.27 (3.38)
2j	1.605 4.67	0.939 4.67	0.734 4.67	0.538 (0.546)	C₂₀H₂₃O₂NSn (80)	Brown, viscous	27.57 (27.73)	56.02 (56.11)	5.47 (5.41)	3.33 (3.27)
2k	1.440 4.18	1.041 4.18	0.857 4.18	0.479 (0.491)	C₂₄H₂₃O₂NSn (79)	Creamish white, solid (189)	24.81 (24.93)	60.43 (60.54)	4.78 (4.86)	2.86 (2.94)
2l	1.395 4.06	1.068 4.06	0.890 4.06	0.465 (0.477)	C₂₅H₂₅O₂NSn (76)	Dark brown, viscous	24.18 (24.22)	61.47 (61.25)	5.06 (5.14)	2.71 (2.85)

Syntheses of

The sodium salt of Schiff base has been synthesized by the reaction of sodium methoxide [prepared by the reaction of sodium (0.316 g, 6.84 mmol) in dry methanol (~10 mL)] and THF solution (~15 mL) of Schiff base (0.98 g, 6.84 mmol). The mixture was heated at reflux for half an hour.

To this solution, a THF solution (~40 mL) of dimethyltindichloride (1.505 g, 6.84 mmol) was mixed, and the reaction mixture was refluxed for ~6 h. NaCl thus precipitated was filtered off, and the excess of solvent was removed under reduced pressure to yield a creamish white solid (m.p. 155°C). The compound was recrystallized from THF/n-hexane mixture. Percent analyses for C₉H₁₇O₂NSn; found (calculated) Sn, 40.72 (40.79) C, 54.96 (55.07) H, 5.65 (5.88) N, 4.73% (4.81) FAB mass spectral data; fragments, m/z (relative intensity) [C₉H₁₇O₂NSn]⁺ • 291 (37.83%), [C₈H₁₆O₂NSn]⁺ • 279 (100%), [C₆H₁₃O₂NSn]⁺ • 251 (30.01%), [C₄H₁₀ONSn]⁺ • 208 (6.17%), [C₃H₈SnO]⁺ • 180 (8.54%), [C₂H₆SnO]⁺ • 166 (4.62%), [CH₃Sn]⁺ • 135 (50.80%).

Mass spectral data of compound

FAB mass spectral data; fragments, m/z (relative intensity) [C₁₅H₂₉O₂NSn]⁺ • 374 (29.11%), [C₁₄H₂₈O₂NSn]⁺ • 361 (100%), [C₁₂H₂₅O₂NSn]⁺ • 334 (18.81%), [C₁₀H₂₂ONSn]⁺ • 291 (7.19%), [C₉H₂₀SnO]⁺ • 263 (3.54%), [C₈H₁₈SnO]⁺ • 249 (9.21%), [C₄H₉Sn]⁺ • 176 (48.07%).

Mass spectral data of compound

FAB mass spectral data; fragments, m/z (relative intensity) [C₁₉H₂₁O₂NSn]⁺ • 414 (30.25%), [C₁₈H₂₀O₂NSn]⁺ • 401 (100%), [C₁₆H₁₇O₂NSn]⁺ • 374 (16.47%), [C₁₄H₁₄ONSn]⁺ • 331 (5.11%), [C₁₃H₁₂SnO]⁺ • 287 (3.89%), [C₁₂H₁₀SnO]⁺ • 273 (8.52%), [C₆H₅Sn]⁺ • 180 (46.45%).

Antimicrobial activity

The ligands (1a–1d) and their corresponding diorganotin derivatives have been screened for the growth inhibitory activity in vitro against bacteria (i.e. S. aureus, B. subtilis, E. coli and P. aeruginosa) and fungi (i.e. Fusarium oxysporum, Trichoderma reesei, Penicillium funiculosum and Aspergillus niger). For both bactericidal and fungicidal assays, in vitro disc diffusion method was adopted because of reproducibility and precision. In this method, the different test organisms were processed separately using a sterile swab over previously sterilized culture medium plates, and the zones of inhibition were measured around sterilized dried discs of Whatman paper no.1 (6 mm in diameter) in two different (2 mg/mL, 4 mg/mL) concentrations of the test solution. Dimethyl sulfoxide was used as solvent, and discs were air dried at room temperature to remove any residual solvent. After this, they were sterilized and inoculated. The plates were initially placed at low temperature for 1 h, so as to allow maximum diffusion of the compounds from the test discs into the plate, and later incubated for 24 h at 34°C in the case of bacteria and 48 h at 27°C for fungi, after which the zones of inhibition could be easily observed. The inhibition zone diameters in each case were recorded and shown in Tables 3 and 4. In account of antimicrobial activity, some images are given in the online supplementary material as Figures S1–S6.

Corresponding author: Yashpal Singh, Department of Chemistry, University of Rajasthan, Jaipur 302004, India, e-mail: yashpaluniraj@gmail.com

Acknowledgments

The authors are thankful to SAIF, Panjab University, Chandigarh, for recording the C, H and N analyses and ¹H, ¹³C and ¹¹⁹Sn NMR spectral studies and also thankful to the Department of Chemistry, Saurashtra University, NFDD Centre, Rajkot, for recording the FAB mass of the three representative compounds.

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Supplemental Material:

The online version of this article (DOI: 10.1515/mgmc-2015-0022) offers supplementary material, available to authorized users.

Received: 2015-6-9

Accepted: 2015-12-19

Published Online: 2016-1-22

Published in Print: 2016-4-1

Supplementary material

Articles in the same Issue

https://doi.org/10.1515/mgmc-2015-0022

Keywords for this article

antimicrobial activities; diorganotin(IV) Schiff base derivatives; FAB mass spectrometry; NMR spectroscopy; pentacoordinated tin

Synthesis, characterization and antimicrobial activity of diorganotin(IV) derivatives of some bioactive bifunctional tridentate Schiff base ligands

Article

Abstract

Introduction

Results and discussion

Syntheses of organotin(IV) derivatives

Spectroscopic studies

Infrared spectra

1H NMR spectra

13C NMR spectra

119Sn NMR spectra

Fast atom bombardment mass spectra

Structural elucidation

Antimicrobial activity

Conclusion

Experimental

Materials and methods

Syntheses of

Mass spectral data of compound

Mass spectral data of compound

Antimicrobial activity

Acknowledgments

References

Supplemental Material:

Supplementary Material

Articles in the same Issue

Articles in the same Issue

Articles in the same Issue

¹H NMR spectra

¹³C NMR spectra

¹¹⁹Sn NMR spectra