核磁共振技术(NMR)在组合化学中的应用

对科学产生最大影响的分析方法是核磁共振技术(NMR),它被广泛用于许多领域.本文结合作者的研究结果评述了NMR在组合化学中的应用,着重于NMR在固相合成的应用、液态NMR和NMR在高通量筛选中的应用.     

Eine neuartige Methode zur Analyse kombinatorischer Substanzbibliotheken mittels paramagnetischer Reporter

A Novel Method to Identify Chemical Compounds of Combinatorial Libraries by the Use of Paramagnetic Tags An EPR method to identify non‐destructively chemical compounds bound to a single solid‐phase‐synthesis bead for combinatorial chemistry applications is discribed. During synthesis chemical inert paramagnetic substances can be attached in small amounts to a solid‐phase‐synthesis resin for tagging of organic compounds or even reaction steps. The identification of single members of a combinatorial library in short time and high sensitivity can be carried out by using an EPR‐spectrometer.     

固相载体上的环加成反应及其应用

固相有机合成和组合化学是近年来发展起来的快速合成数种有机化合物的新方法。本文介绍了在固相载体上进行的环加成反应, 及其在有机合成及反应机理研究中的应用。     

固相有机合成研究进展

组合化学技术给固相有机合成带来了新的发展契机,同时也提出了新的发展要求。目前这一研究领域发展迅速,应用范围不断扩大,技术日臻完善。本文综述了近期固相有机合成研究方面的最新进展。     

The use of FTICR-MS to detect chemical tags from a combinatorial library

The use of tagging in combinatorial chemistry permits tracking of the solid phase as it is taken through iterative split and mix cycles. Several analytical approaches to the identification of tags (and hence the chemical history of the support) have been described. We describe herein a novel chemical tagging strategy for combinatorial solid phase chemistry. The identities of the tags attached to a single bead are discovered by the high resolution, accurate mass technique of Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS).     

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.     

Digital light-directed synthesis. A microarray platform that permits rapid reaction optimization on a combinatorial basis

Solution reactions using photogenerated reagents (Gao, X.; Yu, P.; LeProust, E.; Sonigo, L.; Pellois, J. P.; Zhang, H. J. Am. Chem. Soc. 1998, 120, 12698) are a potentially powerful means for combinatorial parallel synthesis of addressable molecular microarrays. In this report, we demonstrate that this chemistry permits combinatorial screening of reaction conditions on a microarray platform. Using this method of optimization and our reaction apparatus, efficient photogenerated acids and reaction conditions suitable for removal of the acid labile protection group on 5'-O of nucleotides are identified in a short period of time. The chemistry platform demonstrated opens new avenues for rapid, simultaneous investigation of multiple reactions using different reagents and reaction parameters directly on a solid support (e.g., a glass plate). The combinatorial screening method described may be extended to include general organic reactions employing photogenerated and conventional reagents as well as a microarray reaction device. This should be especially valuable for efficient synthesis of addressable organic compound libraries.     

Is high‐resolution magic angle spinning NMR a practical speciation tool for cheese samples? Parmigiano Reggiano as a case study

High-resolution magic angle spinning (HRMAS) NMR is probably the most apt NMR method to analyze complex materials involving a solid phase, e.g. foodstuffs. We present here an HRMAS analysis of grated cheese (Parmigiano Reggiano). A full NMR characterization of this cheese allows the identification of the presence of fatty acids (saturated and unsaturated), amino acids and other small organic molecules. Since the presence and relative concentration of these molecules have previously been shown to correlate with organoleptic, origin and age characterization, HRMAS NMR of cheese is likely to provide a good complimentary tool for the analysis of this food material.     

High resolution magic angle spinning NMR for analyzing small molecules attached to solid support

Solid phase synthesis has become a routine technique in combinatorial chemistry. The need in analytical methods to characterize nondestructively resin bound molecules has been fulfilled by the introduction of High Resolution Magic Angle Spinning (HR MAS) NMR of solvent swollen beads. HR MAS NMR can give solution like proton NMR spectra and one- and two-dimensional NMR techniques are amenable, allowing detailed structure analysis. Recent developments are the application of a diffusion filter to suppress solvent signals and dipolar recoupling techniques to gain spatial information. HR MAS NMR has been applied to monitor reactions and elucidate reaction products.     

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.     

利用离子液体负载反应底物的有机合成

综述了固相、液相组合化学中以可溶性离子液体为载体的有机合成新概念及最新研究进展,并主要介绍了离子液体作为载体负载反应底物在有机合成中的一些应用,如有关的重要有机反应、组合化学、小分子库合成等。该方法具有上载率高、适用反应范围宽、分离纯化简便、结构检测容易和可回收重复使用等诸多优越性,这对于传统的固相、液相合成方法是一个重大的进步。     

High-resolution magic-angle spinning NMR for the identification of reaction products directly from thin-layer chromatography spots

We have investigated the prospect of identifying organic reaction products directly from separated thin-layer chromatography (TLC) spots with high-resolution magic-angle spinning (HRMAS) NMR. The concept is to use the TLC spots for NMR analysis so that spectra can be obtained before the reaction is worked up, but without having to elute the product from the TLC stationary phase. Thus, the separated spot is scraped from the plate, transferred to an HRMAS sample rotor, and suspended with a deuterated solvent. Herein, we describe the effects of having the stationary phase present during NMR acquisition. Using a Varian 4 mm gHX Nanoprobe and rotenone as a test compound, we found that the presence of the stationary phase during NMR acquisition resulted in (i) a large, broad 'background' signal near 4.6 ppm and (ii) a decrease in the signal-to-noise ratio due to the adsorption of the product molecules to the adsorbent. However, both effects could be adequately and conveniently eliminated. The background signal was removed by using either a CPMG pulse sequence or chemical exchange. The adsorption was avoided by using a more polar solvent system. Finally, we found that spectra with good signal-to-noise ratio and resolution could be acquired in a matter of minutes even for cases of limited product concentration. Therefore, we believe the technique has value and provides the organic chemist with another option to obtain NMR data critical for structural elucidation or verification.     

样品制备与处理的进展——无溶剂萃取技术

本文讨论了现代分析化学的重要领域之一, 样品制备及前处理技术的进展--无溶剂萃取技术。包括气相萃取、超临界流体萃取、膜萃取、固相萃取、固相微萃取等方法。简述了这些方法的原理及其应用, 探讨了样品制备与前处理技术的发展动向。     

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.     

Recent developments in the combinatorial synthesis of nitrogen heterocycles using solid phase technology

Recognizing the potential of combinatorial chemistry to accelerate drug discovery and development, most pharmaceutical and related industries are seriously looking toward combinatorial synthesis of compounds in order to facilitate the identification of 'lead' molecules. In particular, solid phase synthesis is the core technology for combinatorial chemistry and is widely used for generating libraries of structurally related compounds. Since many drugs contain the nitrogen heterocyclic component and since heterocycles possess a high order of structural diversity, a precise overview of recent progress in the combinatorial synthesis of nitrogen heterocycles using solid phase methodology would be useful. Since the progress in solid phase synthesis of organic molecules has been reviewed regularly from 1992 to 1998, only the development of solid phase combinatorial synthetic approaches of small nitrogen heterocycles since 1999 will be reviewed here. This review describes the solid phase synthesis of azepanes, benzodiazepines, benzimidazoles, benzothiazepines, cinnolines, indolizines, beta lactams, oxazepins, oxazoles including benzisooxazoles, hydantoins, piperidines, pyrimidines, pyrazolones, quinolones, trizolopyridazines and thiazoles.     

SPE and purification of DNA using magnetic particles

Superparamagnetic particles have been attractive for molecular diagnostics and analytical chemistry applications due to their unique magnetic properties and their ability to interact with various biomolecules of interest. This paper presents a critical overview of magnetic nano ‐ and microparticles used as a solid phase for extraction and purification of DNAs. The mechanisms of DNA binding to the surface of functionalised magnetic particles are described. The most widely used materials including silica supports, organic polymers and other materials, mostly containing magnetite or paramagnetic metallic elements are reviewed. The main application areas of magnetic particles for DNA separation are briefly described.     

固相有机反应和分析方法

综述了近几年固相有机反应和分析方法的最新进展。固相有机反应包括取代、缩合、环加成、氧化还原反应等, 可以形成碳碳键、酰胺键等, 满足官能团的变换; 与固相有机反应相适应的有机分析方法包括对单个树脂微球所连接化合物进行官能团分析(FTIR)方法和结构确定方法(MAS NMR)。这些技术能够更好地使组合化学应用到药物开发研究之中。     

组合化学在功能材料合成方面的应用

组合化学方法是当今材料科学和化学领域的研究热点。组合化学方法首先在新药的合成领域得到应用, 很快就以其合成周期短、合成的样品数量大、节约经费等诸多优点而拓展到功能材料的合成等其它领域。组合化学的方法有许多种, 按照反应相的不同可以分为液相中的组合合成法和固相中的组合合成法, 固相组合合成又可以根据所选用的掩模方式的不同而分为二分阴影掩模法、四分阴影掩模法、可移动百叶窗式掩模法等几种, 可以根据材料合成的实际需求加以选择。     

Enabling routine fluorous capping in solid phase peptide synthesis

We describe here the use of polyfluorinated trivalent iodonium salts as efficient and robust capping reagents during solid phase peptide synthesis using either t-Boc or Fmoc chemistry. Standard protocols established for solid phase peptide synthesis can be utilized without any change in solvent or reagent conditions. The capping reaction was carried out at sites where amino acid coupling steps failed. At the termination of the synthesis, the crude peptide mixture obtained from release of materials from the resin, is either simply centrifuged in aqueous solution to yield pure peptide, or purified by passage through fluorous silica gel in solvents with high water content. We envision that the chemistry and reagents described here will find wide use in peptide and protein chemistry, and also in combinatorial library synthesis where terminal amines are coupled to reaction partners.     

Preparation of new polyfunctional magnesiated heterocycles using a chlorine-, bromine-, or iodine-magnesium exchange

The reaction of heteroaryl iodides with i-PrMgBr (ca. 1.0 equiv) in THF provides the corresponding magnesiated heterocycles. Functional groups such as an ester, cyano, or chloride functions are tolerated in these new Grignard reagents if the exchange can be performed below -20 degrees C. This is the case for all heterocycles bearing electron-withdrawing groups or chelating functions facilitating the iodine-magnesium exchange. In many cases, the exchange can be extended to heteroaryl bromides, and a case of a chlorine-magnesium exchange is described with tetrachlorothiophene. This new preparation of functionalized heteroarylmagnesium compounds provides after reaction with various electrophiles a new entry to a broad range of polyfunctional pyridines, imidazoles, furanes, thiophenes, pyrroles, antipyrines, and uracil derivatives. The application of the halogen-magnesium exchange in the solid phase allows the performance of solid-phase synthesis, with potential applications for combinatorial chemistry.