Abstract:
In the present study, nine series of organotin(IV) carboxylates have been synthesized by the
reaction of tri-, di- and monoorganotin(IV) chlorides or diorganotin(IV) oxides with carboxylate
ligands in dry toluene. The ligands used were N-[(2-methoxyphenyl)]-4-oxo-4-[oxy]butanamide
(HL1), N-[(4-methoxyphenyl)]-4-oxo-4-[oxy]butanamide (HL2), N-[(4-methoxy-2- nitrophenyl)]
-4-oxo-4-[oxy]butanamide
(HL4),
(HL3),
N-[(2-methoxy-5-nitrophenyl)]-4-oxo-4-[oxy]butanamide
N-[(2-methoxyphenyl)]carbamoylbenzoic
acid
(HL5),
N-[(4-methoxy-2-
nitrophenyl)]carbamoylbenzoic acid (HL6), N-[(2-methoxy-5-nitrophenyl)]carbamoylbenzoic
acid
(HL7),
N-[(4-methoxy-2-nitrophenyl)]-4-oxo-4-[oxy]butenamide
(HL8)
and
N-[(2-
methoxy-5-nitrophenyl)]-4-oxo-4-[oxy]butenamide (HL9). The coordination mode of ligands,
structural confirmation and geometry assignment of the complexes both in solid and solution
states were made, using different analytical techniques such as FT-IR, multinuclear (1H, 13C and
119
Sn) NMR and X-ray single crystal analysis. Based on these results, the ligands appeared to
coordinate the Sn atom through carboxylate moiety. The triorganotin(IV) derivatives mostly
demonstrate trigonal bipyramidal geometry both in solid and solution state with few exceptions
of tetrahedral geometry. Octahedral geometry was proposed for diorganotin(IV) carboxylates in
solution state based on NMR.
The interaction of the synthesized compounds with DNA was investigated by UV-visible
spectroscopy. A hypochromic effect along with obvious bathochromic shift (red shift) was
observed. These are the signs of intercalative mode of interaction. The negative values of ∆G
assign the spontaneity of complex-DNA adduct formed.
Some of the synthesized complexes were also screened for their antibacterial and antifungal
activities against various medically important bacteria and fungi. The triorganotin(IV)
derivatives have bactericidal and fungicidal action more than diorganotin(IV) complexes. Most
of the compounds were found to have biological activity comparable to the reference drugs and
some were found even more active. These observations suggest that these compounds may be
used as bactericides and fungicides in future.
The antitumor and anticancer activities of the representative compounds present a new line of
antitumor agents and could also serve as a potential source of chemoprotective agent(s) which is
the major challenge for the chemists at the present time.
The synthesized compounds were also screened for the antileishmanial activity and found that
some of the compounds exhibit strong antileishmanial activity even higher than that of standard
drug, amphotericin B. This study, therefore, demonstrated the potential use of these compounds
as a source of novel agents for the treatment of leishmaniasis.
One of the representative series was also screened for in vitro urease inhibition activity against
Jack bean urease and some of the compounds showed excellent activity of urease inhibition,
even more than the standard drug itself.
They were tested for their catalytic activity in biodiesel synthesis. They possess high capability
of catalyst in the conversion of corn oil into biodiesel. In present work, an environmentally
benign process for the production of biodiesel from corn oil using a heterogeneous catalyst was
developed and upto 99% conversion of oil into biodiesel was obtained. Thus the synthesized
compounds may be used as one of the best choice catalyst in future.