Hydrothermal phase equilibria studies on some of the rare earth oxides of Lanthanide group

Tareen, Jalees Ahmed Khan

15 July 1978

Hydrothermal phase equilibria

Inorganic and Physical Chemistry

Studies in the atomic spectrometric determination of selenium, mercury, and rare earth elements

Harris, Lindsay R

01 January 2012

The field of analytical chemistry is very important to today's society as more and more regulations and legislations emerge regarding trace elements in food, consumer products, medicines, and the environment. Like many areas of science, the current goals of trace elemental measurements and speciation are to increase knowledge on the subject and to improve upon current techniques by enhancing the figures of merit, such as accuracy and reproducibility, meanwhile balancing with the cost and time of analysis. The topics covered in this work were investigated primarily through the use of inductively coupled plasma mass spectrometry (ICP-MS) and inductively coupled plasma optical emission spectrometry (ICP-OES). The phenomenon of compound-dependent responses in plasma spectrometry is discussed, seeking possible causes of it and offering some advice on how to prevent it. A new method was developed for the speciation of selenium in dietary supplements using anion-exchange chromatography ICP-MS. A novel method for the determination of total mercury at trace concentrations in rice was developed for use with conventional ICP-MS. Inductively coupled plasma mass spectrometry was also used for fingerprinting the rare earth elements in Maya archaeological pottery for provenance studies.

Inorganic chemistry|Physical chemistry

Molecular modeling of proton transfer mechanisms, energetics and rates in zeolites and proton exchange membranes

Viswanathan, U

01 January 2011

We have modeled proton transfer using quantum chemical methods in important catalytic material namely Zeolite and polymeric systems to design anhydrous proton exchange membranes for fuel cells (charge transporting materials). In the H-Y Zeolite proton transfer study, we computed the total mean rate coefficient for proton transfer in bare H-Y Zeolite, for comparison with NMR experiments and previous calculations. The proton transfer energies were calculated using two-layer ONIOM calculations on an 8T-53T cluster, where xT indicates x tetrahedral atoms. Rate coefficients were computed using truncated harmonic semi-classical transition state theory. The zero-point energy (ZPE) corrected proton site energies in H-Y (FAU structure) were found to be O3 (0 kJ mole -1), O1 (2.1 kJ mole-1), O2 (16.1 kJ mole-1 ) and O4 (17.5 kJ mole-1), in quantitative agreement with previous calculations and in qualitative agreement with neutron diffraction occupancies. The ZPE corrected activation energies range from 35 to 123 kJ mole-1. Total mean rate coefficients were found to exhibit a strong non-Arrhenius temperature dependence, with apparent activation energies in the range ca. 60-100 kJ mole-1 at high temperature, and ca. 3 kJ mole-1 at low temperature. This low-temperature value reflects thermally assisted tunneling to a site with slightly higher energy. NMR experiments by Sarv et al. and Ernst et al. report apparent activation energies of 61 and 78 kJ mole -1, respectively, extracted from temperature ranges 298–658 and 610–640 K. Our theoretically computed apparent activation energies for these temperature ranges are 72 and 79 kJ mole-1, respectively, in quite good agreement with experiment. In the Grotthuss proton transfer and design criteria for anhydrous proton exchange membrane study, we have modeled structures and energetics of anhydrous proton-conducting wires: tethered hydrogen-bonded chains of the form ··· HX ··· HX ··· HX ···, with functional groups HX = imidazole, triazole and formamidine; formic, sulfonic and phosphonic acids. We have applied density functional theory (DFT) to model proton wires up to 19 units long, where each proton carrier is linked to an effective backbone to mimic polymer tethering. This approach allows the direct calculation of hydrogen bond strengths. The proton wires were found to be stabilized by strong hydrogen bonds (up to 50 kJ mole-1) whose strength correlates with the proton affnity of HX [related to pK b(HX)], and not to pKa(HX) as is often assumed. Proton translocation energy landscapes for imidazole-based wires are sensitive to the imidazole attachment point (head or feet) and on wire architecture (linear or interdigitated). Linear imidazole wires with head-attachment exhibit low barriers for intrawire proton motion, rivaling proton diffusion in liquid imidazole. Excess charge relaxation from the edge of wires is found to be dominated by long-range Grotthuss shuttling for distances as long as 42 Å, especially for interdigitated wires. For imidazole, we predict that proton translocation is controlled by the energetics of desorption from the proton wire, even for relatively long wires (600 imidazole units). Proton desorption energies show no correlation with functional group properties, suggesting that proton desorption is a collective process in proton wires. In the aim of mimicking water, phenolic systems were studied using LSDA/6-311G(d,p). We find using density functional theory calculations on phenolic dimers that their polymers have low re-orientation barrier 13.7 kJ mole-1 compared to the imidazole/triazole systems in which the whole group has to rotate. This study shows that the dynamical nature of the hydrogen bonds in the system is very important to consider when searching for a proton transferring functional group for anhydrous proton exchange membranes.

Inorganic chemistry|Physical chemistry

Synthetic and X-ray structural studies of pentabenzylcyclopentadienyl transition metal complexes

Tsai, Woei-Min

01 January 1991

An improved synthetic route to pentabenzylcyclopentadiene, $\rm C\sb5Bz\sb5H$, has been developed. Both pentabenzylcyclopentadiene and an isomer were obtained depending on the reaction conditions. Structural assignments of both compounds have been investigated based on $\sp1$H NMR, $\sp{13}$C NMR, $\sp1$N 2D COSY NMR spectral and X-ray crystallographic studies. Pentabenzylcyclopentadienyl-lithium, $\rm C\sb5Bz\sb5Li$, was readily prepared from pentabenzylcyclopentadiene and n-butyl-lithium. Both $\rm C\sb5Bz\sb5H$ and $\rm C\sb5Bz\sb5Li$ have been used in the syntheses of the "sandwich" compounds: decabenzyl-, pentabenzyl-, and pentamethylpenta-benzyl-ferrocene, as well as the preparation of the "half-sandwich" compound: $(h\sp5$-$\rm C\sb5Bz\sb5)Mn(CO)\sb3$, $(h\sp5$-$\rm C\sb5Bz\sb5)Re(CO)\sb3$, $\lbrack (h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2\rbrack \sb2$, $(h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2R$ (where R = H, Me, SiMe$\sb3$, SnMe$\sb3$, Cl, I), and $(h\sp5$-$\rm C\sb5Bz\sb5)TiCl\sb3$. The reaction of pentabenzylcyclopentadiene and Fe(CO)$\sb5$ produced a mixture of $(h\sp4$-$\rm C\sb5Bz\sb5H)Fe(CO)\sb3$ and $\lbrack (h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2\rbrack \sb2$. Treatment of $\lbrack (h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2\rbrack \sb2$ with Na/Hg generated $(h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2\sp-Na\sp+$. Subsequent reactions of this anion with CH$\sb3$COOH, MeI, SiMe$\sb3$Cl, or SnMe$\sb3$Cl, produced $(h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2$-R (where R = H, Me, SiMe$\sb3$, SnMe$\sb3$, respectively) in good yield. A reaction of $(h\sp4$-$\rm C\sb5Bz\sb5H)Fe(CO)\sb3$ with trityl cation led to the formation of $\lbrack (h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb3\rbrack \sp+$; following by the addition of LiCl, $(h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2$Cl was obtained. $(h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2$I can also be prepared from the reaction of $(h\sp4$-$\rm C\sb5Bz\sb5H)Fe(CO)\sb3$ with n-BuLi, followed by the addition of MeI in THF. A reaction between trimethylsilylindene and TiCl$\sb4$ in hexane formed (indenyl)titanium trichloride in 52% yield. All the above compounds have been well-characterized by $\sp1$H NMR, $\sp{13}$C NMR, IR, and mass spectrometry, as well as by elemental analyses. Many of the new compounds were obtained as single crystals, and X-ray crystallographic studies of several of them are described. Some of the compounds, such as the isomer of pentabenzylcyclopentadiene and $\lbrack (h\sp5$-$\rm C\sb5Bz\sb5)Fe(CO)\sb2\rbrack \sb2$, cannot be completely elucidated in terms of their structures at the present time, however.

Triarylborane-BODIPY Conjugates : White Light Emission, Multi-color Cell Imaging and Small Molecule Based Solar Cells

Sarkar, Samir Kumar

January 2017

Luminescent boron containing materials find numerous applications in modern technologies such as display/lighting, bio-imaging and sensing. Thus, investigations of structure-property relationships in organic luminescent compounds to understand their molecular and bulk properties are of fundamental importance. The main thrust of this thesis is the development of facile synthetic routes for boron containing novel polyads and study their structure-property correlations and to utilize this information to design functional materials with desired properties such as multiple emission, bio imaging, anion sensing and organic photo voltaic characteristics. This thesis contains seven chapters and the contents of each chapter are described below. Chapter 1 This chapter is a concise overview of the recent developments in the chemistry of boron based molecular systems such as triarylborane and BODIPYs. This chapter also highlights the basic nature of broad emissive materials. In addition, an advance in the frontier areas such as bio imaging is discussed in brief. Chapter 2 This chapter describes the structure and optical properties of a new triad (Borane-Bithiophene-BODIPY) 1. Triad 1 exhibits unprecedented tricolour emission when excited at borane centred high energy absorption band and also acts as a selective fluorescent and colorimetric sensor for fluoride ion with ratiometric response. The experimental results are supported by computational studies. Chapter 3 Two fluorescent compounds with similar absorption profiles and complementarily emissive properties can be regarded as the ideal couple for the generation of white-light. Two structurally close and complementarily fluorescent boron based molecular siblings 2 and 3 were prepared. The luminescence properties of individual triads were modulated to an extent to complement each other by controlling the intramolecular energy transfer in triads by fine-tuning the dihedral angle between fluorophores in 2 and 3. A binary mixture of 2 and 3 emitted white-light. Chapter 4 This chapter deals with a straight forward strategy for the generation of white-light emission in aqueous media. Using a blue-emissive AIE-active (aggregation-induced emission) 1, 8-naphthalimide- based sensitizer and a boron-dipyrromethene based red emitter as a dopant, water dispersible nanostructures with tunable emission features are produced. The white-light emissive (WL) nano-aggregates are stable at neutral pH and have been elegantly utilized for four-colour cell imaging (including near- infrared imaging). Chapter 5 This chapter describes the design and development of a NIR emitting triarylborane decorated styryl-BODIPY (4) via a facile synthetic route. Incorporation of TAB entities results in a significantly red shifted broad emission in 4 (compared to compound M3 which is devoid of TAB unit). The near coplanar orientation of Ar3B planes and BODIPY core results in a highly efficient (TAB to BODIPY) EET process in 4. Conjugate 4 acts as a highly selective and sensitive fluoride sensor with naked eye visual response as well as ratiometric fluorescent response. The dual emission in fluoride bound 4 possibly results from the restricted partial TAB to BODIPY energy transfer. Chapter 6 This chapter describes how the energy of transitions of the broad emissive molecular triads can be fine-tuned by judiciously changing the spacer oligothiophene length. A series of triarylborane and BODIPY conjugates (TAB-π-BODIPY) has been designed, and synthesized by a combined strategy of changing the connection mode between the two units, extending the conjugation size by introducing terthiophene, quaterthiophene, and pentathiophene units. The electrochemical and photophysical behavior of these conjugates were investigated. The experimental findings were rationalized by density functional theory calculations. Chapter 7 This chapter describes design and development of boron based novel electron acceptor BDY for the bulk-heterojunction solar cell. The electron mobility values of BDY was found to be of the order of standard PCBM. Bulk-heterojunction was fabricated using BDY as the electron acceptor layer. The power conversion efficiency of the newly developed solar cells with BDY as electron acceptor is much higher than the value obtained for standard cells with PCBM as the electron acceptor.

Triarylborane-BODIPY Conjugates

Triarylboranes

BODIPY Dyes

Borane-bithiophene-BODIPY Triad

Luminescent Boron

White-light Emission

Inorganic and Physical Chemistry

Rational Design Facile Synthesis of Boryl Anilines : Intriguing Aggregation Induced Emission and External Stimuli Responsive Properties

Sudhakar, Pagidi

January 2015

The main thrust of this thesis is the development of facile synthetic routes for simple boryl anilines and study their structure-property correlations in both solid and solution states and to utilize this information to design functional materials with desired properties such as aggregation induced emission, mechanofluorochromism, and thiol sensors. This thesis contains eight chapters and the contents of each chapter are described below. Chapter 1 The first chapter is an introduction to the theme of the thesis and presents a general review on the present work with emphasis on photophysics of triarylboron based donor-acceptor systems and their applications in various fields. In addition, advances in boron chemistry in the new frontier areas such as aggregation induced emission and mechanochromism are discussed in brief. Chapter 2 The second chapter deals with the general experimental techniques and synthetic procedures utilized in this work. Chapter 3 This chapter describes the rational design and synthesis of triarylborane bearing Unsubstituted amines, namely borylanilines (3.1-3.5). Compounds 3.1-3.4have similar donor and acceptor centres but differ their molecular conformations and also differ in the relative positions of amine moiety (para and meta). Compounds 3.1-3.4 contain one amine group while 3.5 contains two amine moieties. These compounds exhibit fascinating electrostatic intermolecular interactions, N −H- - -π in the crystal structure of 3.1, 3.2 and 3.4 and N −H--N interactions in crystal structure of 3.5. The solution state optical properties of 3.1-3.5 are typical of donor-acceptor (D-A) systems. Interestingly, compounds 3.3 and 3.5 showed unprecedented mechanochromic luminescent properties. Upon grinding, compound 3.3 showed color changes from blue to cyan blue and 3.5 showed intriguing color changes from blue to green and these color changes were found to be reversible. Single crystal X-ray diffraction analysis of 3.5BP (blue emission color crystal) and 3.5GP (green emission color crystal) clearly show that the color changes are due to the difference in their solid state packing. Chapter 4 In chapter 4, the design and facile synthesis of boron based donor-acceptor (D-A) systems such as borylanilines 4.4-4.9 (D= -NH2 for 4.4-4.6 and -NMe2 for compounds 4.7-4.9) are reported. Compounds 4.4, 4.5 and 4.6 contain one, two or three -NH2 moiety(ies), respectively. Compounds 4.7, 4.8 and 4.9 contain one, two or three –NMe2 moiety(ies), respectively. A systematic investigation has been carried out to rationalize the effect of donor-acceptor ratio on the ICT process in borylanilines 4.4-4.9. The aryl spacer between donor amine and acceptor boron is kept the same in all the compounds to avoid the electronic effect of spacer on the ICT characteristics of these compounds. In the case of compounds 4.4-4.6, the increase in the number of donor -NH2 moieties does not affect their absorption profile, while in the case of compounds 4.7-4.9, the absorption spectra are shifted bathochromically with an increase in the number of donor-NMe2 moieties. Photoluminescence (PL) of 4.4-4.6 is significantly blue shifted with an increase in number of –NH2 moieties, while the PL of 4.7-4.9 was slightly blue shifted. The absorption and PL features of 4.4-4.6 are sensitive to the polarity of the solvent medium. In contrast, absorption profiles of 4.7-4.9 are not sensitive to the polarity of the solvent medium. The PL of these compounds is affected by the polarity of the solvent medium. Chapter 5 This chapter deals with triarylboron based fluorescent probes (5.1-5.4) for the selective detection of thiophenols over aliphatic thiols. The probes were constructed by conjugating luminescent borylanilinies with luminescent quencher 2,4-dinitrobenzene sulfonyl (DNBS) moiety. In compound 5.1 and 5.2 the DNBS moiety is positioned at the para position with respect to the triarylborane moiety, while in 5.3 and 5.4 the DNBS moiety(ies) is(are) at the meta position(s). Probes 5.1-5.4 showed selective turn-on fluorescence response towards thiophenol. The fluorescence “off-on” switching mechanism of 5.1-5.4 against thiophenols was fully elucidated by theoretical calculations. Probes 5.1-5.4 are also capable of detecting thiophenols in the intra cellular environments. Chapter 6 Design, facile synthesis and aggregation induced emission properties of a new series of novel triarylboron tethered N-aryl-1,8-naphthalimides (TAB-NPIs) 6.1-6.7 are described in this chapter. Systematic structural perturbation has been used for fine-tuning the optical and morphological properties of TAB- NPIs in both solid as well as in aggregated state. Compounds 6.1-6.7 are weekly luminescent in solutions. In contrast, all compounds (except compound 6.4) are strongly luminescent in the solid state and aggregated state in THF-H2O mixtures. The presence of sterically hindered boryl unit in 6.1-6.7 has endowed these molecules with unique AIE characteristics by preventing co-facial arrangements of NPI moieties. The propeller shape arrangement of TAB moiety in 6.1, 6.2, 6.5, 6.6 and 6.7 effectively prevents the aggregation induced emission quenching (AIEQ) and induce strong emission in the condensed state. In the solid state, compounds 6.1, 6.4, 6.5, and 6.6 generate an interesting supramolecular structure via intermolecular C-H--- and C-H---O interactions. No face to face intermolecular π---π interactions were found in the crystal structures of 6.1, 6.4, 6.5, and 6.6. This precludes the excimer formation which can be detrimental to the radiative process in these molecules. The scanning electron microscopy (SEM) images of as prepared samples of 6.1-6.7 clearly indicate that the morphology of these compounds strongly depends on the molecular conformations and number of naphthalimide moieties in the TAB-NPI conjugates. Chapter 7 This chapter deals with design, synthesis and optical properties of novel dimesitylboryl appended perylenediimides. A simple synthetic strategy has been developed for the construction of novel TAB-PDIs conjugates. These conjugates can be conveniently synthesised by condensation of boryl anilines with perylene tetracarboxylic acid anhydride. The incorporation of TAB moiety enhanced the solubility of perylen bisimides in common organic solvents. The PL quantum yield of both 7.1 and 7.2 strongly depends on the excitation wavelength. Lower Pl efficiency observed for 7.1 and 7.2 upon excitation in the boryl dominated absorption region may be due to the photon induced electron transfer form mesityl units of boryl to perylene bisimide moiety. The morphology as well as emission colours of supramolecular architectures of both 7.1 and 7.2 can be modulated by controlling the concentrations of DCM solutions of these compounds. Both the compounds showed selective fluorogenic response for F-1 and CN-1 anions. The simple synthetic strategy reported in this chapter can be conveniently exploited for the construction of TAB conjugates of semiconducting organic anhydrides. Chapter 8 Novel planar chiral Lewis acids 8.3(SP, SS), 1-phosphino-2-borylferrocenes 8.4(SP) and 2-phosphino-1-borylferrocenes 8.4(RP) have been synthesized from a readily accessible ferrocene sulphinate precursor. Adopting a simple synthetic approach and a single precursor, enantiomerically pure SP and RP isomers have been prepared. It would be worthwhile to investigate the catalytic properties of compounds 8.3(SS), 8.4(SP) and 8.4(RP). It would also be interesting to replace the mesityl groups on boron with other electron deficient groups like pentafluorophenyl and 1,3,5-trifluoromethylphenyl to fine tune the Lewis acidity of boron center and to set-up a general route to enantiomerically pure Planar Chiral Frustrated Lewis Pairs (PCFLP’s).

Facile Synthesis

Structure Property Correlation

Mechanotloarochromism

Thiol Sensors

Triarylborane (TAB)

Borylanilines

Thiophenols

Naphthalimides

Perylene Diimides

Anilines-Boron

Inorganic and Physical Chemistry

Activation of H-X (X = H, Si, B, C) Sigma Bonds in Small Molecules by Transition Metal Pincer Complexes

Ramaraj, A

January 2017

No description available.

Transition Metal Pincer Complexes

Sigma Complexes

Heterolysis of H-H Bond

Pincer Ligands

Dihydrogen Complexes

Ruthenium Pincer Complex

Sigma Bond Activation

Inorganic and Physical Chemistry

Triarylborane Functionalized Dicyanovinyl and Acetylacetone Based Molecular Platforms : Building Blocks for Multiple Anion Sensors and Efficient Phosphorescence Emitters

Rajendra Kumar, G

January 2016

Triarylborane Functionalized Dicyanovinyl and Acetylacetone Based Molecular Platforms: Building Blocks for Multiple Anion Sensors and Efficient Phosphorescence Emitters The main objective of this thesis is to design a simple strategy for triarylborane based multiple anion sensors and development of triarylborane incorporated phosphorescent metal complexes. The thesis consists of eight chapters and the contents of each chapter are given below. Chapter 1 This chapter gives a general introduction to recent advances relevant to the theme of the thesis. A review of the fundamental characteristics of triarylboranes and their applications in various fields such as chemical sensors and optoelectronics is presented. Advances in boron chemistry in the areas such as anion sensors, solid state emissive and phosphorescence materials are discussed in detail. The scope of the thesis is outlined at the end of the chapter. Chapter 2 The second chapter deals with the general experimental techniques and synthetic procedures followed in this thesis. Chapter 3 This chapter deals with a rational design strategy for differential identification of fluoride and cyanide ions using TAB based sensors. In general, most of the triarylboranes give similar optical responses towards fluoride and cyanide ions as they follow similar sensing mechanism. In order to circumvent this problem, two TAB-DCV conjugates (1 and 2) are designed and synthesised. The DCV unit is highly specific for cyanide ion owing to the presence of electrophilic carbon center. Probes 1 and 2 differ in steric crowding around the boron center. The less crowded boron center in 1 binds with fluoride as well as with cyanide ions giving similar optical response (luminescence is quenched in presence of F¯ and CN¯). In the case of 2, selectivity of boron center towards fluoride is tuned by increasing the steric crowding around the boron unit. The dicyanovinyl unit acts as selective sensing site for cyanide ions. As a result, 2 gives different fluorogenic response towards the anions F¯ and CN¯ which were considered as interfering anions in TAB based sensor chemistry. Thus, a modular design principle is developed for differential identification of fluoride and cyanide ions using TAB. Chapter 4 In this chapter, detailed photophysical studies of TAB-amine-DCV conjugates and colorimetric discrimination of fluoride and cyanide ions are discussed. Presence of amine based donor between the two electron deficient sites enhances the electronic conjugation in 3−5. Since there are two different acceptor sites with a common donor, two distinct charge transfer transition bands are observed in the visible region of electromagnetic spectrum. The absorption and emission spectra of these compounds show pronounced sensitivity to solvent polarity, signifying large excited state dipolmonents. Anion binding studies confirms that these compounds are highly selective towards fluoride and cyanide ions. Fluoride ions selectively interact with boron center and block the corresponding charge transfer transition thereby leading to a distinct colour change which is observable by naked eye. On the other hand, cyanide interacts with boron as well as DCV unit and blocks both the charge transfer transitions which results in disappearance of colour. Hence, compounds 4 and 5 exhibit different colorimetric signals for fluoride and cyanide ions. Since the absorption bands of 3 do not fall in the visible region, it does not show any colorimetric response towards the aforementioned anions. The anion sensing mechanisms are established by 1H, and 19F NMR studies. Chapter 5 This chapter presents a systematic study of the effect of length of π-electronic conjugation on the optical properties and anion sensing abilities of a series of TAB-oligothiophene-DCV conjugates (6−8). Their absorption as well as emission bands undergo redshift upon increasing the number of thiophene units between TAB and DCV units as the π-electronic conjugation in 6−8 is greatly dependent on the number of thiophene units. Their fluorescence emission is highly sensitive to solvent polarity. In the case of 6, the emission band undergoes a redshift with reduced intensity. In the case of 7 the emission band undergoes a redshift but the intensity is not affected by solvent polarity. In the case of 8, the emission band undergoes redshift with enhanced intensity in polar solvents. Interestingly, 7 and 8 show solvent viscosity dependent fluorescence. Structural reorganisation is restricted in viscous medium and results in enhanced emission for 7 and 8. Further, these compounds exhibit selective response towards the fluoride and cyanide ions with different colorimetric responses. Test strips made up of probes 7 and 8 have potential application in identifying fluoride and cyanide ions in aqueous medium. Chapter 6 This chapter describes synthesis and optical characterisation of triarylborane incorporated acetylacetone (acacH) ligands (9, 10) and their borondifluoride complexes (11, 12). AcacH ligands and BF2 complexes show solvent dependent emission phenomena due to the involvement of charge transfer transition. Their optical properties are highly dependent on molecular conformations. Complex with duryl spacer (12) exhibits more red shifted emission in polar solvents due to the enhanced charge transfer transition facilitated by twisted rigid geometry. In presence of fluoride and cyanide ions, the borondifluoride complexes are not stable. The anions concomitantly interact with tricoordinate boron as well as acac-BF2 unit to give rise to complex pattern of photoluminescence spectral changes during the titration experiment. The binding pathway and the possible species involved are established with the help of 1H, 19F and 11B NMR spectral studies in presence of the anions. Complexes 11 and 12 act as selective chemodosimetric sensors for fluoride and cyanide ions. Chapter 7 In this chapter, the synthesis and optical characterisations of triarylborane conjugated cyclometalated platinum complexes are discussed. A series of square planar platinum complexes are synthesised with different cyclometalating ligands. Complexes (13−18) exhibit a range of luminescence from green to red in solution as well as in the solid state. Their emission intensities are highly sensitive towards atmospheric oxygen suggesting that they originate from a triplet excited state. A maximum of 85% quantum yield is observed for complex 15 in solution state while complex 14 showed a maximum of 58% quantum yield in solid state. Complexes with rigid molecular conformation (14, 16 and 18) showed higher luminescence quantum yield than those having phenyl spacer (13, 15 and 17). The sterically encumbered boryl (-BMes2) group significantly reduces π-π stacking between the square planar entities. Thus, complexes 13−18 show bright luminescence in solid state compared to model complexes without boryl group. The effect of Lewis acidic boron center on luminescence behaviour is explored by fluoride binding studies. Chapter 8 This chapter is divided into two parts. Part-I describes the synthesis and optical characterisation of triarylborane conjugated cyclometalated iridium complexes (19−24). They are brightly luminescent in solution state with high sensitivity towards atmospheric oxygen. Complex 20 shows a highest quantum yield of 91%. Interestingly, under ambient atmospheric conditions, they exhibit a rare type of dual emission. Life time data suggest that the lower energy emission band originates from cyclometalated iridium based triplet excited state while higher energy emission band originates from boryl ased singlet excited state. Fluoride binding at the boron site results in luminescence quenching; evidently, tri-coordinate boron has a major contribution to the luminescence features of these iridium complexes. Part-II deals with synthesis of triarylborane conjugated pyrazole ligand (25) and its binuclear iridium complexes (26−28) in which two iridium centers are bridged by hydroxo as well as pyrazolato ligands. These binuclear iridium complexes exhibit higher luminescence quantum yield than TAB-acac-Iridium complexes (mononuclear complexes; part I). Binding of fluoride ions at the boron center has a minor impact on their luminescence nature. High sensitivity of their luminescence towards atmospheric oxygen indicates the involvement of triplet excited state in their emission process.

Triarylboranes

Dicyanovinyl

Acetylacetone Molecular Platforms

Phosphorescence Emitters

Bidendate Lewis Acids

Anion Sensors

Dicyanovinyl Chromophores

Platinum Complexes

Iridium Complexes

Inorganic and Physical Chemistry

Controlling Conformation of Macromolecules by Immiscibility Driven Self-Segregation

Mandal, Joydeb

January 2014

Controlling conformation of macromolecules, both in solution and solid state, has remained an exciting challenge till date as it confronts the entropy driven random coil conformation. Folded forms of biomacromolecules, like proteins and nucleic acids, have served as role-models to the scientists in terms of designing synthetic foldamers. The folded functional forms of proteins and nucleic acids have been shown to rely heavily on various factors, like directional hydrogen bonding, intrinsic conformational preferences of the backbone, solvation (e.g. hydrophobic effects), coulombic interactions, charge-transfer interactions, metal-ion complexation, etc. Chapter-1 discusses various designs of synthetic polymers explored by research groups world-over to emulate the exquisite conformational control exercised by biomacromolecular systems. Our laboratory has been extensively involved since 2004 in designing charge-transfer complexation induced folding of flexible donor-acceptor (DA) polymeric systems, such as those shown in Scheme 1. It was observed that such polymers adopt a folded conformation in polar solvents, like methanol, in the presence of an excess of an appropriate alkali metal ion. To explore folding in the solid state, Jonas and co-workers recently showed that a polyethylene-like polyester with long alkylene segments containing periodically located pendant propyl group forms a semicrystalline morphology with alternating crystalline and amorphous regions primarily because of the periodic folding of the backbone due to the steric exclusion of the propyl branches from the crystalline domains. In order to explore immiscibility-driven folding of polyethylene-like polyesters, Roy et al. designed a periodically grafted amphiphilic copolymer (PGAC) containing long alkylene segments (mimicking polyethylene) and pendant oligoethyleneglycol chains at periodic intervals (Scheme 2). Scheme 2: Proposed folding of a periodically grafted amphiphilic copolymer It was demonstrated that immiscibility between the hydrocarbon backbone and pendant PEG segments drives the polymer to adopt a folded zigzag conformation as shown in Scheme 2. The above synthetic strategy, however, does not permit easy structural variation of the side chain segments because the side-chain segment is covalently linked to the malonate monomer. In Chapter-2, a more general strategy to prepare periodically grafted copolymers has been described. In an effort to do so, we designed a series of clickable polyesters carrying propargyl/allyl functionality at regular intervals along the polymer backbone, as shown in Scheme 3. Scheme 3: Periodically clickable polyesters for the preparation of periodically grafted copolymers The polyesters were prepared by reacting either 2-propargyl-1,3-propanediol, 2,2-dipropargyl-1,3-propanediol or 2-allyl-2-propargyl-1,3-propanediol with an alkylene diacid chloride, namely 1,20-eicosanedioic acid chloride, under solution polycondensation conditions. Since these polyesters carry either, one propargyl, two propargyls or one propargyl and one allyl group on every repeat unit, it provides us an opportunity to synthesise exact graft copolymers with one side chain, two side chains or even two dissimilar side chains per repeat unit. In Chapter-3, the periodically clickable polyesters were reacted with MPEG-350 (PEG 350 monomethyl ether) azides using Cu(I) catalyzed azide-yne click reaction to generate periodically grafted amphiphilic copolymers (PGAC) carrying crystallizable hydrophobic backbone and pendant hydrophilic MPEG-350 side-chains (Scheme 4). Since the PGACs carry either one or two pendant MPEG-350 chains on every repeat unit, it allowed us to examine the effect of steric crowding on the crystallization propensity of the central alkylene segment. Scheme 4: Functionalization of periodically clickable polyesters with MPEG 350 azide by azide-yne click reaction From DSC studies, it was observed that increase in steric crowding at junctions resulting from increased side-chain volume hinders effective packing of the hydrocarbon backbone. As a result, both transition temperatures and the enthalpies associated with these transitions decreases. SAXS and AFM studies revealed the formation of lamellar morphology with alternate domains of PEG and hydrocarbon. Based on these observations, we proposed that self-segregation between hydrophobic backbone and hydrophilic side-chains induce the backbone to adopt a folded zigzag conformation (Scheme 5). Scheme 5: Schematic depiction of self-segregation induced folding of PGAC and their assembly on mica surface (AFM image) In order to study the effect of solvent polarity on conformational evolution of the periodically grafted amphiphilic copolymers, we randomly incorporated pyrene in the backbone of the polymer by reacting a small fraction (~ 5 mole %) of the propargyl groups with pyrene azide. Fluorescence study of the pyrene labelled polymer showed that increase in solvent polarity increases the intensity of the excimer band dramatically; this suggests the possible collapse of the polymer chain to the folded zigzag form. In an extension of this work, the PGAC was further used as template to synthesise layered silicates that appears to replicate the lamellar periodicity seen in the polymer. In order to study the effect of reversing the amphiphilicity on self-segregation, in Chapter-4, we synthesised a series of clickable polyesters carrying PEG segments of varying lengths, namely PEG 300, PEG 600 and PEG 1000, along the polymer backbone. The polymers were prepared by trans-esterification of 2-propargyl dihexylmalonate with different PEG-diols. These polyesters were then clicked with docosyl (C22) azide using Cu(I) catalyzed azide-yne click reaction to generate the desired periodically grafted amphiphilic polymers carrying crystallizable hydrophobic pendant chains at periodic intervals; the periodicity in this case was governed by the length of the PEG diols (Scheme 6). Scheme 6: PGACs carrying hydrophilic PEG backbone and crystallizable hydrophobic pendant docosyl chains Varying the average periodicity of grafting provided an opportunity to examine its consequences on the self-segregation behavior. Given the strong tendency of the pendant docosyl segments to crystallize, DSC studies proved useful to analyse the self-segregation; DOCOPEG 300 clearly exhibited the most effective self-segregation, whereas both DOCOPEG 600 and DOCOPEG 1000 showed weaker segregation. Based on the observations from DSC studies, we proposed that the PEG backbone adopts a hairpin like conformation (Scheme 7). Scheme 7: Proposed self-segregation through hairpin like conformation of backbone PEG segments In order to confirm the bulk morphology, we carried out small angle X-ray scattering (SAXS) and atomic force microscopic (AFM) studies. The SAXS profiles confirmed the observations from DSC studies, and only DOCOPEG 300 exhibited well-defined lamellar ordering. Thus, it is clear that the length of the backbone PEG segment (volume-fraction) strongly influences the morphology of the PGACs. Based on the inter-lamellar spacing from SAXS and the height measurements from AFM studies (Scheme 8), we proposed that these polymers form lamellar morphology through inter-digitation of the pendant docosyl side-chains. The observations from Chapters 3 and 4 suggested that the crystallization of the backbone has a dramatic effect on the conformation of the polymer backbone. In order to explore the possibility of independent crystallization of both backbone and pendant side-chains, the periodically clickable polyesters, described in Chapter-2, were quantitatively reacted with a fluoroalkyl azide, namely CF3(CF2)7CH2CH2N3 using Cu(I) catalyzed azide-yne click reaction; Chapter-5 describes these polyesters carrying long chain alkylene segments along the backbone and either one or two perfluoroalkyl segments located at periodic intervals along the polymer chain (Scheme 9). DSC thermograms of two of the samples showed two distinct endotherms associated with the melting of the individual domains, while the WAXS patterns confirm the existence of two separate peaks corresponding to the inter-chain distances within the crystalline lattices of the hydrocarbon (HC) and fluorocarbon (FC) domains; this confirmed the occurrence of independent crystallization of both the backbone and side chains. Scheme 10: Left-variation of SAXS profile of all three polymers as a function of temperature, Right- molecular modelling of representative FC-HC-FC triblock structures. Interestingly, a smectic-type liquid crystalline phase was observed at temperatures between the two melting transitions. SAXS data, on the other hand, revealed the formation of an extended lamellar morphology with alternating domains of HC and FC (Scheme 10). The inter-lamellar spacing calculated from SAXS matches reasonably well with those estimated from TEM images. Based on these observations, we proposed that the FC modified polymers adopt a folded zigzag conformation whereby the backbone alkylene (HC) segment becomes colocated at the center and is flanked by the perfluoroalkyl (FC) groups on either side, as depicted in Scheme 11. Melting of alternate HC domains first leads to the formation of a smectic-type liquid crystalline mesophase, wherein the crystalline FC domains retain the smectic ordering; this was confirmed by polarizing light microscopic observations. Scheme 11: Schematic presentation of self-segregation induced folding of polymer chains; and hence crystallization assisted assembly of these singly folded chains to form lamellar structure One interesting challenge would be to create unsymmetrical folded structures, wherein the top and bottom segments of the zigzag folded form would be occupied by two different segments, such as PEG and FC, whereas the backbone alkylene segment would form the central domain; this would lead to the possible formation of consecutive domains of PEG, HC and FC through immiscibility driven self-segregation process. In Chapter-6, several approaches to access such systems have been described; one such design that could have resulted in the successful synthesis of a periodically clickable polymer carrying orthogonally clickable propargyl and allyl groups along the backbone in an alternating fashion is depicted in (Scheme 12). The parent polyester was successfully synthesized and the propargyl group was first clicked with the FC-azide to yield the FC-clicked polyester; however, several attempts to click MPEG-SH onto the allyl groups using thiol-ene click reaction failed. Scheme 12: Scheme for the synthesis of alternating orthogonally clickable polymer In order to accomplish our final objective, we chose to first prepare the FC-clicked diacid chloride and polymerize it with an azide-alkyne clickable macro-diol, as depicted in Scheme 13; this approach was successful and yielded the desired clickable polyester bearing the FC segments at every alternate location. This polymer was then clicked with PEG-750 azide to yield the final targeted polymer that carries mutually immiscible FC and PEG-750 segments at alternating positions along the polymer backbone. The occurrence of self-segregation of FC, PEG-750 and the alkylene backbone (HC) was first examined by DSC studies, which appeared to suggest the presence of three peaks, although these were not very well-resolved. Scheme 13: Schematic for the synthesis of the polymer carrying FC and PEG 750 alternatingly along the backbone A schematic depiction of the anticipated organization of such unsymmetric folded macromolecules is shown in Scheme 15; it is evident that because of mutual immiscibility, the layers will be organized such that the FC domains of adjacent layers will be together and similarly the PEG domains of adjacent layers will also be together. Such an organization would lead to an estimated spacing that would correspond to a bilayer of the folded structures. Interestingly, SAXS study (Scheme 14) reveals the formation of lamellar morphology with a d-spacing of 14.6 nm. Scheme 14: Figure 6.10: SAXS profile of the polymer PE-FC-PEG 750 In order to gain an estimate of the expected inter-lamellar spacing, the end-to-end distance of a model repeat-unit was computed to be ~ 9.4 nm. It is, therefore, evident that the inter-lamellar spacing of 14.6 nm seen in the SAXS is significantly larger and must represent a bilayer type organization (Scheme 15). In this regard it is important to say that the organization of these alternatingly functionalized folded chains should give a variety of d-spacings. Because of highest electron density contrast of FC among PEG, HC and FC, we proposed that the d-spacing calculated from the SAXS profile corresponds to ‘d4’ in Scheme 15. This first demonstration of the formation of zigzag folded unsymmetric entities bearing dissimilar segments on either side of the folded chain holds exciting potential for a variety of different applications and beckons further investigations. Scheme 15: Schematic for the proposed self-assembly of the singly folded polymer chains

Macromolecules

Immiscible Polymers

Macromolecular Folding

Hydrogen Bonding

Immiscibility Driven Self-Aggregation

Polymers

Polymerization

Biopolymers

Biomacromolecules

Macromolecular Conformation

Copolymers

Crystalline Polymers

Polyesters

Inorganic and Physical Chemistry

Synthesis, Structural Elucidation and Anticancer Activity Studies on Metal Complexes of Nucleic Acid Constituents and their Derivatives

Sivakrishna, Narra

January 2016

Metal-nucleic acid interaction studies have been gaining attention due to their biological and chemical importance. Nucleic acids are negatively charged bio-polymers and neutralization of their negative charge is essential for the stability and function. In the cells, organic positive ions (positively charged amino acids and polyamines) and some of the metal ions (e.g. Na+, K+, Mg2+...etc) neutralize the charge of nucleic acids. Whereas, interactions of some metal ions (e.g. Cd2+, Hg2+…etc) with nucleic acids destabilize the structure. The stability and conformation of nucleic acids alter due to metal interactions. Further, metal interactions with nucleic acids can bring changes in conformation of ribose, H-bonding and π-π stacking interactions. To understand the metal interactions with nucleic acids, various spectroscopic techniques are being used. However, X-ray crystallographic technique is advantageous over all other spectroscopic techniques since it gives thorough detail of coordination mode and structure. However, crystallization of large molecules like nucleic acids with metals is associated with great difficulty. In order to simplify the problem, nucleic acid constituents and derivatives have been used as model systems for metal-nucleic acid interactions. Nucleic acid constituents and derivatives are multidentate ligands. Moreover, binding mode of metal with nucleic acid constituents and derivatives depends on various factors include pH, temperature, type of metal…etc. Further, understanding of metal nucleic acid interactions can aid to develop new anticancer drugs targeting nucleic acids. For example, cisplatin is a platinum based anticancer drug, which coordinates to N(7) of guanine in DNA brings cell death. There have been several reports in literature on the complexes of metal nucleic acid constituents. However, much more research is warranted for thorough understanding of metal-nucleic acid interactions. On the other hand, nucleic acid constituents and derivatives are used extensively in anticancer drug development. Some of nucleic acid constituent derivatives, 5-Fluro uracil and 6-Mercaptopurine, are currently in use for the treatment of colorectal cancer and leukemia, respectively. Moreover, cisplatin is a platinum based anticancer drug used in the treatment of various types of cancers. However, use of these drugs for long time poses severe side effects and drug resistance. Most of the side effects are due to non bio-compatibility of drugs. To overcome problems associated with present anticancer drugs, bio-compatible metal based anticancer drug development could be an attractive and alternative strategy. To address this, in this study, we report synthesis of a number of new metal complexes of nucleic acid constituents and their derivatives and characterization by various spectroscopic techniques. Also, the interactions of Ni, Cu and Zn ions with various nucleic acid constituents and their derivatives have been elucidated by single crystal X-ray crystallography. Interestingly, Ni, Cu and Zn ions showed various coordination modes to nucleic acid constituents and their derivatives. Further, anticancer studies were carried out for all these complexes in various cancer cell lines. Several complexes showed better cytotoxicity than the well-known drug cisplatin. My thesis work is divided into five parts based on the nature of molecules. I. Synthesis, X-ray crystallographic and anticancer studies on metal (Zn/Ni) complexes of guanine (G) based nucleic acid constituents In order to understand (Zn/Ni) interactions with guanine based nucleic acid constituents and their anticancer activity, several (Zn/Ni) complexes of 5′-GMP, 5′-IMP and hypoxanthine complexes were prepared. The synthesized complexes are (1) [Zn (5′-GMP)]n.11H2O, (2) [Ni (5′-GMP)2 Na2 (μ-OH2)3 (H2O)8].2H2O, (3) [Ni (5′-IMP)2Na2 (H2O)12]n.5H2O and (4) [Ni (hx)2 (H2O)4] Cl2 [Here 5′-GMP = 5′-Guanosine Mono Phosphate, 5′-IMP = 5′-Inosine Mono Phosphate and hx = Hypoxanthine). These complexes were characterized by various spectroscopic and X-ray crystallography techniques. Complex 1: The X-ray structure revealed that zinc is coordinated to 5′-GMP through N(7) position of purine and phosphate moieties, the uncoordinated water molecules are making interesting complicated network of hydrogen bonds in the unit cell. The geometry of zinc coordination centre is distorted tetrahedral. Fascinatingly, zinc exhibited two different coordination environments. In one case, all phosphate oxygens participated in coordination with zinc. In second case, N(7) position of purine and phosphate oxygens participated in coordination with zinc. Moreover, zinc formed a coordination polymer with 5′-GMP. The conformation of ribose changed upon zinc interaction with 5′-GMP from C(3′)-endo to C(2′)-endo, these results suggest that zinc interaction with nucleic acids may change their conformation. Complex 1 is stabilized in solid state by H-bonding and π-π stacking interactions. Complex 2: In complex 2, 5′-GMP is coordinated to nickel through N(7) position of purine but phosphate moiety did not take place in coordination. Two molecules of 5′-GMP and four water molecules coordinated to nickel and formed distorted octahedral geometry. The charge of complex 2 is balanced by sodium coordination to sugar hydroxyl groups and nickel coordinated water molecules. The geometry of sodium coordination centre is distorted octahedral. The conformation of 5′-GMP is altered due to nickel interaction. Moreover, complex 2 is stabilized in solid state by H-bonding and π-π stacking interactions. Complex 3: Nucleotide 5′-IMP also showed similar coordination modes like 5′-GMP towards nickel, where N(7) position of purine participated in coordination with nickel and phosphate moieties did not coordinate to nickel. Two molecules of 5′-IMP and four water molecules participated in coordination with nickel and formed distorted octahedral geometry. Interestingly, the charge of complex 3 is balanced by sodium coordination to sugar hydroxyl moieties. The geometry of sodium coordination centre is distorted octahedral. Moreover, nickel is forming coordination polymer with 5′-IMP. Further, nickel interactions with 5′-IMP brought changes in the conformation of ribose moiety. These results suggest that nickel interactions with nucleic acids may bring changes in their conformation. Interestingly, right hand helical structure formation is observed for complex 3 in crystal structure. Further, the chirality of complex 3 was confirmed by circular dichroism studies. Complex 3 is stabilized by both H-bonding and π-π stacking interactions in solid state. Complex 4: Surprisingly, nickel is coordinated to hypoxanthine through N(9) position of purine in acidic conditions and not through N(7) or N(3). The coordination mode of nickel with hypoxanthine is different from complexes 2 and 3. Two hypoxanthine moieties are coordinated to nickel in axial manner. The geometry of nickel coordination centre is distorted octahedral. Further, complex 4 is stabilized by H-bonding and π-π stacking interactions in solid state. Cytotoxicity studies of complexes 1-4 on various cancer cell lines revealed that complex 1 is better cytotoxic than complexes 2-4. Moreover, complex 1 exhibited comparable cytotoxicity with cisplatin on various cells lines and induced apoptotic cell death. II. Synthesis, structure elucidation and anticancer activity of copper-adeninyl complexes In order to understand copper-adenine interactions and anticancer activity, several copper complexes of adenine derivatives were prepared. Here, most of adenine derivatives used in complex preparation is known as cycline dependent kinase inhibitors. Prepared copper complexes are 1) [Cu (N6-benzyl adenineH)2Cl3 ].Cl.2H2O, 2) [Cu (2-amino-N6-benzyladenineH)2Cl3].(2-amino-N6-benzyl adenineH)2.3Cl.5H2O, 3) [Cu (α-(Purin-6-ylamino)-p-toluenesulfonamide H)2Cl4], 4) [Cu (kinetinH)2 Cl3].Cl.2H2O, 5) [Cu (N-1H-purine-6-yl-alanineH) (H2O) Cl3].H2O, 6) [(Cu (N-1H-purine-6-yl-alanineH)2Cl3).(Cu(N-1H-purine-6-yl-alanineH)Cl)2(μ-Cl)2].Cl.4H2O. All these complexes were characterized by X-ray crystallography and various spectroscopic techniques. Complex 1: Synthesis and X-ray structures of complex 1 were reported in literature. However, anticancer activity of complex 1 is not known. Therefore, it was prepared based on the reported lines to assess the anticancer activity. The anticancer activity of complex 1 was studied on various cell lines. Interestingly, complex 1 exhibited better cytotoxicity than cisplatin in MCF-7 and MDA-MB-231 cell lines. Complex 2: Ligand 2-amino-N6-benzyl adenine is coordinated to copper through N(9) of purine. In addition, two uncoordinated 2-amino-N6-benzyl adenine, three chloride and five water molecules are making it as a co-complex with uncoordinated ligands. The copper coordination centre adopted distorted trigonal bipyramidal geometry [3+2] with τ = 0.671 (α-β/60, where α, β are two greatest valence angles of coordination centre). Further, complex 2 is stabilized in solid state by both H-bonding and π-π stacking interactions. H-bonding is observed between N-H···Cl. Uncoordinated water molecules formed six-member rings with H-bonding network. The π-π stacking interactions are observed between phenyl and purine moieties. Complex 2 exhibited better cytotoxicity than 2-amino-N6-benzyl adenine and copper salt. Complex 3: Ligand α-(2-Amino purin-6-ylamino)-p-toluene sulfonamide is coordinated to copper through N(9) position and protonation is observed at N(3) position. Two molecules of α-(2-Amino purin-6-ylamino)-p-toluene sulfonamide and four chloride ions are forming a distorted octahedral geometry with copper. Complex 3 is stabilized by N-H···Cl and N-H···O H-bonding. Further, complex 3 exhibited better cytotoxicity than cisplatin in U251 cells. Complex 4: Kinetin is coordinated to copper through N(9) position of purine. Protonation is observed on N(3) position and balanced the charge of complex 4. Two molecules of kinetin and three chloride moieties are coordinated to copper and forming distorted trigonal bipyramidal geometry [3+2] with τ = 0.431. Moreover, complex 4 is stabilized by both H-bonding interactions and π-π stacking interactions. The H-bonding of complex 4 is observed between N-H···Cl and C-H···Cl. The π-π stacking interactions are observed between furanyl aromatic ring and imidazole ring of purine. Complex 4 exhibited better cytotoxicity than kinetin and copper salt. Complex 5: The N-1H-purine-6-yl-alanine is coordinated to copper through N(9) position of purine. Complex 5 crystallizes in the monoclinic space group P21 with Z=4. One molecule of N-1H-purine-6-yl-alanine, two chloride ions and one water molecule coordinated to copper. The geometry of copper coordination centre is distorted trigonal bipyramidal [3+2] with Cu(1) τ1 = 0.613 and Cu(2) τ2= 0.671. Protonation is observed on N(3) position. Complex 5 is stabilized by both H-bonding and π-π stacking interactions. The H-bonding of complex 5 is observed between N-H···Cl and C-H···Cl. The π-π stacking interactions are observed between imidazole moieties. Moreover, complex 5 exhibited better cytotoxicity than N-1H-purine-6-yl-alanine and copper salt. Complex 6: Complex 6 is a co-complex, where two different complexes are co-crystallized. The crystal structure of complex 6 indicate that geometry of Cu(1) and Cu(2) coordination centre are distorted trigonal bipyramidal [3+2] with τ1 = 0.3261 and τ2 = 0.8, respectively. Two molecules of N-1H-purine-6-yl-alanineH are coordinated to Cu(2) through N(9) position of purine. The N-1H-purine-6-yl-alanineH ligands are arranged in geometry in trans manner with respect to axis passing through the N(9) atom and copper. Whereas, in second co-complex two N-1H-purine-6-yl-alanineH are coordinated to Cu(1) through N(9) and N(3) position of purine. Both Cl(1) and Cl(3) coordinated to copper are forming a bridge between copper. In addition, one uncoordinated chloride and two water molecules are present in the unit cell. Complex 6 is stabilized in crystalline state by both H-bonding and π-π stacking interactions. Complex 6 exhibited better cytotoxicity than complex 5, N-1H-purine-6-yl-alanine and copper salt on various cell lines. III. Synthesis, structure and anticancer activity of zinc complexes of adenine derivatives In order to understand zinc interaction with adenine and their anticancer activity, several zinc complexes of adenine derivatives were prepared. The prepared complexes are (1) [Zn (N6-benzyladenineH).Cl3].2H2O, (2) [Zn2 (μ -N6-benzyladenine)2( μ-H2O)2(H2O)4].(OTf)4.H2O, (3) (N6-benzyl adenineH2) [ZnCl4].2H2O, (4) [Zn (2-Amino-N6-Benzylpurine)Cl3).2-Amino-N6-BenzylpurineH).EtOH, (5) (2-Amino-N6-(3-picoyl)purineH2)[ZnCl4].H2O, (6)(2-Amino-N6-(3-picoyl)purineH2)[ZnCl4].HCl, (7) (2-Chloro-N6-(3-picoyl) purineH2) [ZnCl4].H2O, (8) ((α-Purine-6-ylamino)-p-toluene sulfonamide H)2[ZnCl4].2HCl.2H2O. Complex 1: The N6-benzyl adenine is coordinated to zinc through nitrogen atom N(7) of purine. One molecule of N6-benzyl adenine and three chloride ions are coordinated to zinc and forming distorted tetrahedral geometry. Interestingly, the nitrogen atom N(1) of purine is protonated. Complex 1 exhibited strong H-bonding interactions between N-H···O, N-H···Cl and N-H···N. The complex 1 showed better cytotoxicity than N6-benzyl adenine and ZnCl2. Complex 2: The N6-benzyl adenine formed a dimeric complex with zinc at neutral pH. Complex 2 crystallizes in the triclinic space group P-1with Z=1. Two Zn metal centres are bridged by two molecules of N6-benzyl adenine through nitrogen atoms N(3) and N(9) of purine forming a di-nuclear complex, further two zinc centres is bridged by two water molecules and other two water molecules on the other side completing the octahedral coordination for the Zn. Complex 2 is stabilized in crystalline state by H-bonding interactions. The H-bonding of complex 2 is observed between O-H···O and N-H···O. Complex 2 exhibited better cytotoxicity than N6-benzyl adenine and ZnCl2 on various cell lines. Complex 3: The N6-benzyladenine is not coordinated to the Zn metal at acidic pH and forms an ion-pair complex. Ion-pair complex 3 crystallizes in the monoclinic space group Cc with Z=4. The protonation is observed at N(1) and N(9) atoms of N6-benzyl adenine. The positive charges on N6-benzyl adenine is neutralized by the presence of two chloride ions in [ZnCl4]2-. Alternative arrangement of cation and anion arrangement is observed in complex 3. Water channel formation is observed between cation and anion arrangement. Moreover, complex 3 is stabilized by H-bonding and π-π stacking interactions. H-bonding is observed in complex 3 between N-H···Cl, O-H···Cl and N-H···O. The π-π stacking interactions in complex 3 are observed between benzyl six-membered aromatic ring and purine six-membered rings. Complex 3 exhibited better cytotoxicity than N6-benzyl adenine and ZnCl2 in various cell lines. Complex 4: Ligand 2-amino-N6-benzyl adenine resulted in a different structure from N6-benzyl adenine with zinc. One molecule of 2-amino-N6-benzyl purine is coordinated to zinc through nitrogen atom N(7) of purine. Surprisingly, one uncoordinated positively charged 2-amino-N6-benzyl purineH is present in the asymmetric unit, which is balancing the charge of zinc complex 4. Protonation is observed on N(3A) atom. Interestingly, tautomeric proton is located on coordinated purine of N(9) atom and uncoordinated purine of N(7A) atom. Geometry of ‘Zn coordination centre’ is distorted tetrahedral. Complex 4 is stabilized by H-bonding and π-π stacking interactions. The H-bonding interaction in complex 4 is observed between N-H···O and N-H···Cl. The π-π stacking interactions are observed between five-member aromatic rings and six-membered aromatic rings. Complex 4 exhibited better cytotoxicity than 2-amino-N6-benzyl purine and ZnCl2 in various cell lines. Complex 5: 2-Amino-N6-(3-picoyl) purine forms an ion-paired complex with zinc at acidic pH. The protonation in 2-Amino-N6-(3-picoyl) purine is observed at N(3) of the purine and picolyl N(14). The positive charge of 2-Amino-N6-(3-picoyl) purine is neutralized by the presence of two chloride ions in [ZnCl4]2-. Moreover, complex 5 exhibited both H-bonding interactions and π-π stacking interactions. The H-bonding interactions are observed between N-H···Cl, N-H···N, O-H···Cl, N-H···O and C-H···N. One uncoordinated water molecule is present in unit cell, which is involved in H-bonding with both ions. The π-π stacking interactions are observed between purine five-membered rings and purine six-membered ring. Complex 5 exhibited better cytotoxicity than cisplatin in HeLa and MDA-MD-231 cells. Complex 6: 2-Amino-N6-(3-picoyl) purine formed similar structure of complex 5 in strong acidic conditions. Complex 6 exhibited both H-bonding and π-π stacking interactions. The H-bonding in complex 6 is observed between N-H···Cl and N-H···N. In complex 6, the π-π stacking interactions are observed between pyridyl six-membered rings and purine six-membered rings. Purine-Purine stacking interactions are observed between purine six-membered ring and five-membered rings. Complex 6 exhibited better cytotoxicity than cisplatin in HeLa, MCF-7, MDA-MB-231 and HeLa-Dox cells. Interestingly, complex 6 arrested (G2/M phase) cell cycle in HeLa and MCF-7 at higher concentration and induced apoptosis. Complex 7: 2-chloro-N6-(3-picoyl) purine formed ion-pair complex with zinc. The protonation in 2-chloro-N6-(3-picoyl) purine is observed on N(9) of purine and N(14) of picolyl atoms. The positive charge of 2-chloro-N6-(3-picoyl) purine is neutralized by the presence of two chloride ions in [ZnCl4]2-. Complex 7 is stabilized by both H-bonding and π-π stacking interactions. The H-bonding is observed between N-H···Cl, O-H···Cl and N-H···O in complex 7. The π-π stacking interactions are observed between pyridyl six-membered ring and six-membered ring of purine. Complex 7 exhibited better cytotoxicity than cisplatin in HeLa, MCF-7, U251 and HeLa-Dox cells. Complex 8: (α-Purine-6-ylamino)-p-toluene sulphonamide formed ion-pair complex with zinc. Ion-pair complex 8, crystallizes in the triclinic space group P-1 with Z=4. The protonation on (α-Purine-6-ylamino)-p-toluene sulfonamide is observed at N(9) and N(1) atoms of purine. The positive charge of the ligand is neutralized by two chloride ions present in [ZnCl4]2 -. The H-bonding is observed between N-H···Cl, O-H···N, N-H···O and O-H···Cl. The π-π stacking interactions are observed between benzyl rings of benzene sulfonamide moieties. Complex 8 exhibited better cytotoxicity than cisplatin in HeLa, MCF-7 and HeLa-Dox cells. Moreover, these complexes induced apoptotic cell death as revealed by Annexin V/PI assay, FACS and microscopy analysis. IV. Synthesis, structure and cytotoxicity studies of zinc complexes of uracil-1-acetic acid and N6-adeninebutyric acid To understand the zinc interactions with nucleic acid constituent derivatives and their anticancer activity, zinc complexes of uracil-1-acetic acid and N6-adeninebutyric acids were prepared. (1) [Zn (uracil-1-acetato)2 (H2O)4] and complex (2) [Zn (N6-adeninebutyric acid)2 (H2O)2]) were characterized by X-ray crystallography and various spectroscopic techniques. The X-ray structures showed acetate moiety coordination to zinc rather than purine and pyrinidine moities. The geometry of zinc coordination centre is distorted octahedral. Complexes 1 and 2 are stabilized by non-covalent interactions. Anticancer studies of these complexes showed better cytotoxicity than cisplatin in MDA-MB-231cells. V. Copper (II) complexes of 6-mercaptopurine, hypoxanthine and uracil-1-acetic acid: Synthesis, structures, antioxidant and potent anticancer activity To delineate copper interactions with purine and pyrimidine derivatives and anticancer activity, several copper complexes of 6-mercaptopurine, hypoxanthine and uracil-1-acetic acid were prepared. The prepared complexes are (1) [Cu (6-MP) (bpy) Cl2], (2) [Cu (hx) (phen) Cl2].H2O and (3) [Cu (bpy)2 (uracil-1-acetato)].6H2O)] (bpy = 2, 2′-bipyridine, phen = 1, 10-phenanthroline, 6-MP = 6-Mercapto Purine and hx = hypoxanthine). All these complexes were chracterized by various spectroscopic and X-ray diffraction techniques. Complexes 1 and 2 crystallize in the monoclinic space groups Cc and C2/c, respectively with eight molecules in the unit cell. All the complexes 1-3 adopt distorted trigonal bipyramidal geometry. Surprisingly, most potent coordination sites of sulfur in 6-MP and acetato in uracil-1-acetato did not participate in coordination with copper. In complexes 1 and 2, the N(7) position of purine and the N(3) position of pyrimidine in complex 3 are coordinated with copper. All these complexes 1-3 are stabilized by non-covalent interactions in solidstate. Anticancer studies showed better cytotoxicity for copper complexes than cisplatin, 6-meracptopurine and temozolomide in various cell lines. Interestingly, copper complexes of 6-MP and hypoxanthine showed antioxidant activity and reduced ROS level in cells. In contrast, copper complex of uracil-1-acetic acid produced ROS in cells. In contrast, copper hypoxanthine showed better cytotoxicity than cisplatin in HeLa-Dox cells. All these complexes induced apoptotic cell death. In summary, we studied the interaction of metal-nucleic acid constituents and derivatives by X-ray crystallography. We found new coordination modes for Ni, Cu and Zn towards various nucleic acid constituents and derivatives. Some of these complexes showed better cytotoxicity than well known anticncer drugs cisplatin, 6-meracptopurine and temozolomide. Complex [Cu (hx) (phen) Cl2].H2O showed better cytotoxicity than cisplatin in doxorubicin resistant (HeLa-Dox) cells. These complexes induced apoptotic cell death in various cancer cells. All in all, the results of present studies/findings could form a potential lead for the development of newer anticancer therapeutics.

Metal Nucleic Acid Interaction

Metal Complexes of Nucleic Acid

Zn/Ni Complexes

Copper-adeninyl Complexes

Zinc Complexes

Copper (II) Complexes

Anticancer Drug Development

Inorganic and Physical Chemistry