SOLID PHASE SYNTHESIS OF ISOXAZOLINES

1. INTRODUCTION A solid phase organic synthesis (SPOS) has increasingly attracted chemist抯 attention over the past decades [1~3]. It was found that the compounds with biological activity are mostly derived from heterocycle structures. It is therefore no…     

SOLID PHASE SYNTHESIS OF ISOXAZOLINES

The solid-phase synthesis of isoxazolines on 2-polystyrylsulfonamidoethanol resin isreported. 2-Polystyrylsuifonamidoethanol resin 1 was reacted with acryloyl chloride to afford2-polystyrylsulfonylamidoethyl acrylate resin 2, which was further reacted with brominatedaldoximes by [3+2] cycioaddition to give isoxazoline resin 4. Resin 4 was treated with aqueous 6mol/L HCI solution to obtain isoxazolines in good yield and purity.     

Recent advances in liquid-phase combinatorial chemistry

In combination with high throughput screening, combinatorial organic synthesis of large numbers of pharmaceutically interesting compounds may revolutionize the drug discovery process. Although combinatorial organic synthesis on solid supports is a useful approach, several groups are focusing their research efforts on liquid-phase combinatorial synthesis by the use of soluble polymer supports to generate libraries. This macromolecular carrier, in contrast to an insoluble matrix, is soluble in most organic solvents and has a strong tendency for precipitation in particular solvents. Liquid-phase combinatorial synthesis is a unique approach since homogeneous reaction conditions can be applied, but product purification similar to the solid-phase method can be carried out by simple filtration and washing. This method combines the positive aspects of classical solution-phase chemistry and solid-phase synthesis. This review examines the recent applications (1995-1999) of soluble polymer supports in the synthesis of combinatorial libraries.     

Regiospecific solid-phase synthesis of substituted 1,2,3-triazoles

A traceless and regiospecific solid-phase synthesis of substituted 1,2,3-triazoles is developed using polystyrene-sulfonyl hydrazide resin. The chemistry is applicable to combinatorial library synthesis.     

Out of the oil bath and into the oven--microwave-assisted combinatorial chemistry heats up

The application of microwave irradiation to expedite solid-phase organic reactions could be the tool that allows combinatorial chemistry to deliver on its promise--providing rapid access to large collections of diverse small molecules. Herein, several different approaches to microwave (MW)-assisted solid-phase reactions and library synthesis are introduced, including the use of solid-supported reagents, multicomponent coupling reactions, solvent-free parallel library synthesis, and spatially addressable library synthesis on planar solid supports. The future impact of MW-assisted organic reactions on solid-phase and combinatorial chemistry could prove to be immense, and methods for further improvement of this strategic combination of technologies are highlighted.     

A facile solid-phase synthesis of 3,4,6-trisubstituted-2-pyridones using sodium benzenesulfinate as a traceless linker

A facile and traceless solid-phase synthesis of 3,4,6-trisubstituted-2-pyridones has been developed using polystyrene sodium benzenesulfinate resin. The chemistry is applicable to combinatorial library synthesis.     

Synthesis and evaluation of poly(oxyethylene glycol) polymer (POP) supports

Mono- and alpha,omega-bis-styryl-oligo(oxyethylene glycol) ethers have been constructed in an efficient two-step synthesis. From these precursors, poly(oxyethylene glycol) polymer (POP) supports of varying monomer and cross-linker composition have been produced. The swelling properties and mass-solvent uptake of these novel materials have been evaluated in a variety of solvents, demonstrating that POP supports exhibit enhanced solvent compatibilities over the commercial resins TENTA-GEL, ARGO-GEL, and Merrifield's resin. The utility of POP supports in solid-phase organic chemistry has also been demonstrated successfully. It is anticipated that these high-loading polymeric supports will have generic application in the solid-phase synthesis of combinatorial libraries and the in situ screening of these libraries in the aqueous environment of a bioassay.     

Qualitative and quantitative analyses of resin-bound organic compounds

Methods for qualitative and quantitative analyses of resin-bound organic compounds are essential tools for chemistry development in solid-phase combinatorial and parallel syntheses. Here we discuss the use of gel-phase 19F NMR, the fluoride ion-selective electrode method, and spectrophotometry for monitoring solid-phase reactions. Our results indicate that the application of these diverse methods for analyzing the outcome of solid-phase combinatorial synthesis are sensitive and conclusive.     

Mass spectrometry and combinatorial chemistry: new approaches for direct support-bound compound identification

Mass spectrometry is a powerful analytical tool allowing rapid and sensitive structural elucidation of a wide range of molecules issued from solution-, solid- and liquid-phase syntheses. Therefore, mass spectrometry has become the most widely used tool to probe combinatorial libraries. A significant portion of the reported combinatorial data are being produced using solid phase organic synthesis. In contrast to indirect strategies where the tethered structures were released from the support into solution to undergo standard mass spectrometric analyses, static - secondary ion mass spectrometry (S-SIMS) has enabled the identification of support-bound molecules without any chemical treatment of the resin bead. Such non-destructive characterization was applied at the bead level and facilitated the step-by-step monitoring of solid-phase peptide syntheses. Side-reactions were also detected. The relevance of S-SIMS in the rehearsal phase of combinatorial chemistry is demonstrated by comparison with infrared and nuclear magnetic resonance (NMR) spectroscopies, the two other techniques investigated in that field. An alternative to solid-phase synthesis consists of assembling molecules on a soluble polymer. This methodology is termed liquid-phase synthesis. Compound characterization is facilitated since the derivatized support is soluble in spectroscopic solvents used in NMR or in electrospray ionization mass spectrometry. The advantages and drawbacks of this approach will be discussed in terms of the direct monitoring of supported reactions during chemistry optimization and rehearsal library validation.     

Combinatorial libraries of bis-heterocyclic compounds with skeletal diversity

Combinatorial solid-phase synthesis of bis-heterocyclic compounds, characterized by the presence of two heterocyclic cores connected by a spacer of variable length/structure, provided structurally heterogeneous libraries with skeletal diversity. Both heterocyclic rings were assembled on resin in a combinatorial fashion.     

A nonacid degradable linker for solid-phase synthesis

Synthesis and applications of two new nonacid degradable linkers as an alternative to the Wang linker for solid-phase synthesis are described. Resin from linker 2 looks superior to linker 1 in terms of yields for both anchoring of the first building block and cleavage and in terms of higher purity of the final product. Use of linker 2 avoids side reactions associated with the use of Wang resin due to an undesired cleavage during final acid treatment.     

Structure based library approach to photosynthesis inhibitors:Combinatorial synthesis of hydrouracil library

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Solid-Phase Synthetic Approach Toward the Synthesis of Oxygen-Containing Heterocycles

Solid-phase organic synthesis is a rapidly expanding area of synthetic chemistry which is being widely exploited in the search for new medicinally important compounds using combinatorial techniques. In recent decades, a large number of reports related to solid-phase synthesis of heterocycles have appeared because of the wide variety in their biological activity. In this review, we report the important role of solid-phase synthesis in the synthesis of oxygen-bearing heterocycles.     

Nitrogen-Containing Six-Membered Heterocycles: Solid-Phase Synthesis

Solid-phase organic synthesis is a rapidly expanding area of synthetic chemistry that is being widely exploited in the search for new medicinally important compounds using combinatorial techniques. In recent decades, a large number of reports related to solid-phase synthesis of heterocycles have appeared because of the wide variety of their biological activity. In this review, we report the important role of solid-phase synthesis in the synthesis of nitrogen containing six-membered ring heterocycles.     

Combinatorial synthesis of heterocycles: solid-phase synthesis of 2-amino-4(1H)-quinazolinone derivatives

A new solid-phase synthesis of various substituted 2-amino-4(1H)-quinazolinones from a resin bound amine component is described. The amine was readily converted to the corresponding polymer bound S-methylthiopseudourea. Condensation with different substituted isatoic anhydrides afforded 2-amino-4(1H)-quinazolinone derivatives. The method is amenable for combinatorial library generation.     

Progression of Organic Reactions on Resin Supports Monitored by Single Bead FTIR Microspectroscopy

We report the time courses of five solid-phase reactions obtained using single bead FTIR microspectroscopy. This time-resolved information aided in the determination of the required reaction time, the nature of the solid-phase reaction, and resin property, effectively assisting in the initial phase of our combinatorial chemistry efforts. Our results showed that solid-phase organic reactions proceed faster than generally speculated. In addition, we have shown that reactions on the surface and in the interior of the bead occur at the same rate for reactions studied. The reaction on the TentaGel resin was shown to be not faster than reactions on Wang resin, suggesting that the diffusion of the substrate into polystyrene bead copolymerized with 1% divinylbenzene is not rate-limiting. Finally, the capability of obtaining IR spectra from the partial surface of a single bead demonstrated the femtomolar detection limit of single bead FTIR microspectroscopy.     

Colorimetric monitoring of solid-phase aldehydes using 2,4-dinitrophenylhydrazine

A simple and rapid method to achieve colorimetric monitoring of resin-bound aldehydes, based on ambient temperature reaction with 2,4-dinitrophenylhydrazine (DNPH) in the presence of dilute acid, has been developed as an adjunct to solid-phase organic synthesis and combinatorial chemistry. By this test, the presence of aldehydes is indicated by a red to dark-orange appearance, within a minute. Alternatively, resins that are free of aldehydes or in which aldehyde functions have reacted completely retain their original color. The DNPH test was demonstrated for poly(ethylene glycol)-polystyrene (PEG-PS), aminomethyl polystyrene (AMP), cross-linked ethoxylate acrylate resin (CLEAR), and acryloylated O,O'-bis(2-aminopropyl)poly(ethylene glycol) (PEGA) supports and gave results visible to the naked eye at levels as low as 18 micromol of aldehyde per gram of resin.     

Multistep synthesis of 2,5-diketopiperazines on different solid supports monitored by high resolution magic angle spinning NMR spectroscopy

The solid-phase synthesis of 2,5-diketopiperazines containing the trans-4-hydroxy-L-proline amino acid residue (Hyp) was performed on Ellman polystyrene, polyoxyethylene-polyoxypropylene (POEPOP), polystyrene-polyoxyethylene NovaSyn, and Wang resins, respectively. The reaction pathway allowed the introduction of different functional groups around the bicyclic scaffold in a combinatorial approach, and it generated mixtures of isomers. A detailed characterization of the single reaction steps by high resolution magic angle spinning (HRMAS) NMR spectroscopy was performed. The NMR spectral resolution of the resin-bound intermediates and final products was greatly influenced by the polymer matrix. The POEPOP resin permitted to obtain HRMAS NMR spectra with a resolution comparable with that of the spectra of the molecules in solution. Moreover, configurational and conformational isomers formed during the solid-phase reaction steps could be detected and easily assigned. Therefore, the combination of the HRMAS NMR technique with the use of nonaromatic resins may become an extremely powerful tool in solid-phase organic synthesis. This approach will allow the monitoring of multistep reactions and the conception of on-bead structural studies either on small molecules or on natural and/or synthetic oligomers.     

Bromate Exchange Resin as an Oxidizing Agent in Organic Synthesis

Bromate exchange resin has been prepared by a simple elution technique and used for the oxidation of aromatic aldehydes to the carboxylic acids. Oxidation is carried out under biphasic condition. Work up is simple. Resin immobilized bromate ions have been used for the first time as an oxidizing agent in organic synthesis.     

Microwave-assisted solid-phase synthesis of 2,5-diketopiperazines: solvent and resin dependence

Solid-phase synthesis of diketopiperazines (DKPs) was preformed using various combinations of resins (polystyrene, TentaGel, ArgoGel, and PEGA) and solvents (toluene, tert-butyl alcohol, water, and toluene/2-butanol (1:4, v/v). The DKPs were synthesized from solid-phase bound dipeptides via intramolecular aminolysis. Both thermal and microwave-assisted solid-phase synthesis of DKPs gave high yields of products independently of resin and organic solvent used; however, only the PEGA resin resulted in high yields of DKPs in water independent of heating method. The short reaction times, high yields, and the possibility to run reactions in water when an appropriate resin is used makes the microwave-assisted solid-phase synthesis the method of choice. The method should be suitable for solid-phase synthesis of diketopiperazine-based libraries.