Delia Miguel

Synthesis of diverse indole-containing scaffolds by gold(I)-catalyzed tandem reactions of 3-propargylindoles initiated by 1,2-indole migrations: scope and computational studies.

Similar to propargylic carboxylates and sulphides, 3-propargylindoles undergo 1,2-indole migrations under cationic gold(I) catalysis. The intermediate Au-carbenoid complex may evolve through different pathways depending on the substituents at the propargylic and terminal positions of the alkyne moiety. Thus, 3-indenylindole derivatives were easily obtained through formal iso-Nazarov or Nazarov cyclizations. DFT computations support the formation of an alkylidenecyclopropane intermediate that undergoes gold-iso-Nazarov or gold-Nazarov cyclizations upon torquoselective ring opening. In addition, 3-dienylindoles could be accessed when none of the referred pathways were accessible and so the intermediate Au-carbenoid complex evolved via a 1,2-C-H insertion reaction. We have also demonstrated that the final products can be obtained in a one-pot protocol from easily available propargylic alcohols and indoles.

Recent applications of Cp2TiCl in natural product synthesis

This review highlights the recent applications of titanocene(III) complexes in the field of natural product synthesis from the seminal precedents to the development of modern catalytic methods. The power of the titanocene(III)-based approaches is demonstrated by the straightforward syntheses of many natural products from readily available starting materials.

Water control over the chemoselectivity of a Ti/Ni multimetallic system: Heck- or reductive-type cyclization reactions of alkyl iodides.

A versatile Ti/Ni multimetallic protocol is described for the efficient catalysis of two different reactions, namely a Heck- and reductive-type cyclization of alkyl iodides, in the absence or presence of water, respectively. Noteworthy, the versatility of Ti(III) chemistry allows an oxidative ending step under reductive conditions to give Heck-type products, and the good H-atom transfer capabilities of Ti(III)-aqua complexes ensure reductive-type cyclizations.

Ti/Pd Bimetallic Systems for the Efficient Allylation of Carbonyl Compounds and Homocoupling Reactions

The allylation, crotylation and prenylation of aldehydes and ketones with stable and easily handled allylic carbonates is promoted by a Ti/Pd catalytic system. This Ti/Pd bimetallic system is especially convenient for the allylation of ketones, which are infrequent substrates in other related protocols, and can be carried out intramolecularly to yield five- and six-membered cyclic products with good stereoselectivities. In addition, Ti/Pd-mediated reductions and Würtz-type dimerisation reactions can be readily carried out from allyl carbonates and carboxylates.

Ti(III)-catalyzed cyclizations of ketoepoxypolyprenes: control over the number of rings and unexpected stereoselectivities.

We describe a new strategy to control the number of cyclization steps in bioinspired radical (poly)cyclizations involving epoxypolyenes containing keto units positioned along the polyene chain. This approach provides an unprecedentedly straightforward access to natural terpenoids with pendant unsaturated side chains. Additionally, in the case of bi- and tricyclizations, decalins with cis stereochemistry have been obtained as a consequence of the presence of the ketone. The preferential formation of cis-fused adducts was rationalized using DFT calculations. This result is completely unprecedented in biomimetic cyclizations and permits the access to natural terpenoids with this stereochemistry, as well as to non-natural analogues.

Reduction Reactions in Green Solvents: Water, Supercritical Carbon Dioxide, and Ionic Liquids

A reduction reaction, in a general sense, is an electrochemical process in which an atom, ion, or molecule earns electrons. In organic chemistry such reduction reactions can be achieved by several methods, including the addition of hydrogen to a molecule or the removal of oxygen or other electronegative substituents. Reduction reactions have been known for a very long time, being developed almost simultaneously to modern chemistry. For example, the first catalytic hydrogenation recorded was the reduction of ethylene and acetylene to ethane in the presence of platinum black, by Von Wilde in 1874. [1] The industrial application of this reaction did not take long, and in 1901 Normann carried out the hydrogenation of fats and oils to change their melting profiles and textures. [2] From that time until now, novel methods and catalysts that make reduction reactions very broad, important, and efficacious chemical transformations have been developed. Nevertheless, and due to its industrial relevance, an extraordinary effort has to be made to develop more environmentally benign conditions. In this sense, this Review is focused on greener alternatives to conduct reduction reactions. Although this is a very wide topic, much of the effort has been focused on developed strategies to recycle and reuse catalysts and solvents, and on finding alternative media that are less contaminating than organic solvents. With respect to this point, water, supercritical CO2, and ionic liquids have emerged as fundamentally greener alternatives to organic solvents. Although the present work is focused on reduction reactions, the reader interested in knowing more about green solvents for organic synthesis will find additional

Toward Multiple Conductance Pathways with Heterocycle-Based Oligo(phenyleneethynylene) Derivatives

In this paper, we have systematically studied how the replacement of a benzene ring by a heterocyclic compound in oligo(phenyleneethynylene) (OPE) derivatives affects the conductance of a molecular wire using the scanning tunneling microscope-based break junction technique. We describe for the first time how OPE derivatives with a central pyrimidine ring can efficiently link to the gold electrode by two pathways presenting two different conductance G values. We have demonstrated that this effect is associated with the presence of two efficient conductive pathways of different length: the conventional end-to-end configuration, and another with one of the electrodes linked directly to the central ring. This represents one of the few examples in which two defined conductive states can be set up in a single molecule without the aid of an external stimulus. Moreover, we have observed that the conductance through the full length of the heterocycle-based OPEs is basically unaffected by the presence of the heterocycle. All these results and the simplicity of the proposed molecules push forward the development of compounds with multiple conductance pathways, which would be a breakthrough in the field of molecular electronics.

Synthesis and photophysics of a new family of fluorescent 9-alkyl-substituted xanthenones.

9-Alkyl xanthenones with different aliphatic pendant groups have been easily prepared by means of nucleophilic addition of the corresponding Grignard derivative to a tert-butyldimethylsilyl ether (TBDMS)-protected 3,6-dihydroxy-xanthenone. The photophysical behavior of the new dyes has been explored by using absorption, steady-state-, and time-resolved fluorescence measurements. We determined the equilibrium constants, visible spectral characteristics, fluorescence quantum yield, and decay times. Remarkably, they retain similar fluorescent properties of fluorescein including the characteristic phosphate-mediated excited-state proton-transfer (ESPT) reaction. 6-Hydroxy-9-isopropyl-3H-xanthen-3-one (5) was investigated in living cells; it presented a good permeability and efficient accumulation inside the cytosol. For the first time, we reported that the requirement of an aryl group at C-9 is no longer needed and new fluorescent sensors can be therefore easily developed.

Titanocene(III)-promoted Barbier-type crotylation of carbonyl compounds.

A mild, highly regio- and stereoselective method for the crotylation of aldehydes and ketones mediated/catalyzed by titanocene(III) is described. Optimized conditions permit the selective generation of γ-adducts in high yields together with high stereoselectivity, with a predominance of anti stereoisomers.

New Dual Fluorescent Probe for Simultaneous Biothiol and Phosphate Bioimaging

The simultaneous detection of relevant metabolites in living organisms by using one molecule introduces an approach to understanding the relationships between these metabolites in healthy and deregulated cells. Fluorescent probes of low toxicity are remarkable tools for this type of analysis of biological systems in vivo. As a proof of concept, different naturally occurring compounds, such as biothiols and phosphate anions, were the focus for this work. The 2,4-dinitrobenzenesulfinate (DNBS) derivative of 9-[1-(4-tert-butyl-2-methoxyphenyl)]-6-hydroxy-3H-xanthen-3-one (Granada Green; GG) were designed and synthesized. This new sulfinyl xanthene derivative can act as a dual sensor for the aforementioned analytes simultaneously. The mechanism of action of this derivative implies thiolysis of the sulfinyl group of the weakly fluorescent DNBS-GG by biological thiols at near-neutral pH values, thus releasing the fluorescent GG moiety, which simultaneously responds to phosphate anions through its fluorescence-decay time. The new dual probe was tested in solution by using steady-state and time-resolved fluorescence and intracellularly by using fluorescence-lifetime imaging microscopy (FLIM) in human epithelioid cervix carcinoma (HeLa) cells.