A bioinspired metal-organic approach to cross-linked functional 3D nanofibrous hydro- and aero-gels with effective mixture separation of nucleobases by molecular recognition.

The direct reaction between Cu(CH3COO)2 and uracil-1-acetic acid in water gives rise to the formation of a hydrogel consisting of entangled nanometric ribbons of a crystalline antiferromagnetic 1D Cu(ii) coordination polymer (CP) decorated with biocompatible uracil nucleobases. This hydrogel is the precursor for the preparation of a meso/macroporous ultralight aerogel that shows a remarkable Young's modulus. As a proof-of-concept of the molecular recognition capability of the terminal uracil moieties anchored at Cu(ii) CP chains, this material has been tested as the selective stationary phase for the separation of nucleobase derivatives in HPLC columns.

Multistimuli Response Micro- and Nanolayers of a Coordination Polymer Based on Cu2 I2 Chains Linked by 2-Aminopyrazine.

A nonporous laminar coordination polymer of formula [Cu2 I2 (2-aminopyrazine)]n is prepared by direct reaction between CuI and 2-aminopyrazine, two industrially available building blocks. The fine tuning of the reaction conditions allows obtaining [Cu2 I2 (2-aminopyrazine)]n in micrometric and nanometric sizes with same structure and composition. Interestingly, both materials show similar reversible thermo- and pressure-luminescent response as well as reversible electrical response to volatile organic solvents such as acetic acid. X-ray diffraction studies under different conditions, temperatures and pressures, in combination with theoretical calculations allow rationalizing the physical properties of this compound and its changes under physical stimuli. Thus, the emission dramatically increases when lowering the temperature, while an enhancement of the pressure produces a decrease in the emission intensity. These observations emerge as a direct consequence of the high structural flexibility of the Cu2 I2 chains which undergo a contraction in CuCu distances as far as temperature decreases or pressure increases. However, the strong structural changes observed under high pressure lead to an unexpected effect that produces a less effective CuCu orbital overlapping that justifies the decrease in the intensity emission. This work shows the high potential of materials based on Cu2 I2 chains for new applications.

MasterChem: cooking 2D-polymers.

2D-polymers are still dominated by graphene and closely related materials such as boron nitride, transition metal sulphides and oxides. However, the rational combination of molecules with suitable design is already showing the high potential of chemistry in this new research field. The aim of this feature article is to illustrate, and provide some perspectives, the current state-of-the-art in the field of synthetic 2D-polymers showing different alternatives to prepare this novel type of polymers based on the rational use of chemistry. This review comprises a brief revision of the essential concepts, the strategies of preparation following the two general approaches, bottom-up and top-down, and a revision of the promising seminal properties showed by some of these nanomaterials.

Halo and Pseudohalo Cu(I)-Pyridinato Double Chains with Tunable Physical Properties.

The properties recently reported on the Cu(I)-iodide pyrimidine nonporous 1D-coordination polymer [CuI(ANP)]n (ANP = 2-amino-5-nitropyridine) showing reversible physically and chemically driven electrical response have prompted us to carry a comparative study with the series of [CuX(ANP)]n (X = Cl (1), X = Br (2), X = CN (4), and X = SCN (5)) in order to understand the potential influence of the halide and pseudohalide bridging ligands on the physical properties and their electrical response to vapors of these materials. The structural characterization of the series shows a common feature, the presence of -X-Cu(ANP)-X- (X = Cl, Br, I, SCN) double chain structure. Complex [Cu(ANP)(CN)]n (4) presents a helical single chain. Additionally, the chains show supramolecular interlinked interactions via hydrogen bonding giving rise to the formation of extended networks. Their luminescent and electrical properties have been studied. The results obtained have been correlated with structural changes. Furthermore, the experimental and theoretical results have been compared using the density functional theory (DFT). The electrical response of the materials has been evaluated in the presence of vapors of diethyl ether, dimethyl methylphosphonate (DMMP), CH2Cl2, HAcO, MeOH, and EtOH, to build up simple prototype devices for gas detectors. Selectivity toward gases consisting of molecules with H-bonding donor or acceptor groups is clearly observed. This selective molecular recognition is likely due to the 2-amino-5-nitropyridine terminal ligand.

Reversible stimulus-responsive Cu(I) iodide pyridine coordination polymer.

We present a structurally flexible copper-iodide-pyridine-based coordination polymer showing drastic variations in its electrical conductivity driven by temperature and sorption of acetic acid molecules. The dramatic effect on the electrical conductivity enables the fabrication of a simple and robust device for gas detection. X-ray diffraction studies and DFT calculations allow the rationalisation of these observations.

5,5'-Diuracilyl Species from Uracil and

Not only UV radiation can bring about the dimerization of the pyrimidine nucleobase uracil, a metal ion can as well! The reaction proceeds by a reductive elimination process of two cis-oriented uracil entities, each bonded to Au(III) through C5 [Eq. (a)]. R/R'=H/CH(3), CH(3)/CH(3), H,C(5)H(9)O(4)

Cytotoxicity, DNA binding, and reactivity against nucleosides of platinum (II) and (IV) spermine compounds.

We describe the synthesis and characterization of a [sperH4][PtCl4]2 salt and of five binuclear platinum (II) and (IV)-spermine compounds of formula [(PtCl2)2(sper)], cis-[(Pt(CH2(COO)2)2(sper)], cis-[(PtCBDCA)2(sper)], (CBDCA = 1,1'-cyclobutanedicarboxylate), cis-trans-cis[(PtCl2(OH)2)2(sper)], and cis-[(PtCl4)2(sper)], respectively. The 1H and 195Pt-NMR analysis of the complexes formed between these compounds and nucleosides indicated that the Pt centers show preferential binding to the N(7) of guanosine and adenosine residues, also being capable of forming bridged structures through the N(7) and N(1). The synthesized Pt-spermine compounds do not form complexes with cytidine residues at 37 degrees C. The circular dichroism, melting, and electrophoretic data of the compounds-DNA complexes show that the Pt(IV)-spermine complexes induce lower DNA conformational changes than their Pt(II) analogs. These results correlate with the IC50 values obtained against MDA-MB 468 and HL-60 human cancer cells which are higher than those of cis-DDP. The [sperH4][PtCl4]2 salt produces a high level of DNA modification and exhibits IC50 values lower than those of cis-DDP.

Synthesis, characterization, and DNA modification induced by a novel Pt-berenil compound with cytotoxic activity.

In the present paper, we show that the reaction of the antipyranosomatid berenil drug with K2PtCl4 resulted in the synthesis of a covalent (Pt(II)-berenil compound of formula [Pt2Cl4(berenil)2]Cl4.4H2O as shown by IR, 1H, 13C, and 195Pt-NMR. The Pt-berenil compound was tested for in vitro antitumor activity against HL-60 and U-937 human leukemic cells. The results show that the LC70 values of the Pt-berenil are about two-fold lower than those of cis-DDP in both HL-60 and U-937 cell lines. Melting data of Pt-berenil:DNA and berenil:DNA complexes indicate that the platinated compound produces on a DNA secondary structure higher compaction than the berenil ligand. The mobility in agarose gels and the circular dichroism spectra of the compounds:DNA complexes revealed, moreover, that both induce drastic changes on a DNA secondary and tertiary structure. The total reflection X-ray fluorescence data showed, in additIon that DNA platination in Pt-berenil:DNA complexes occurs within minutes after addition of the drug, in contrast to what that observed in cis-DDP:DNA complexes. On the basis of these results, we propose that in Pt-berenil, the berenil ligand acts as a carrier of the active cis-P(II) centers towards DNA.