The use of optical spectroscopy in combinatorial chemistry

Infrared and Raman spectroscopy allow direct spectral analysis of the solid‐phase, thus avoiding the tedious cleavage of compounds from the solid support. With diagnostic bands in starting materials or products, infrared and Raman spectroscopy are efficient in monitoring each reaction step directly on the solid phase. Consequently, infrared and Raman spectroscopy have evolved as the premier analytical methodology for direct analysis on the solid support. While infrared transmission spectroscopy is a general analytical method for resin samples, internal reflection spectroscopy is especially suited for solid polymer substrates known as “pins” or “crowns.” Single bead analysis is done best by infrared microspectroscopy, whereas photoacoustic spectroscopy allows totally nondestructive analysis of resin samples. With an automated accessory, diffuse reflection spectroscopy provides a method for high throughput on‐bead monitoring of solid‐phase reactions. Providing identification based on molecular structure, HPLC‐FTIR is, therefore, complementary to LC‐MS. Additionally, Raman spectroscopy as a complement to infrared spectroscopy can be applied to resin samples and—using a Raman microscope—to single beads. Fluorometry as an extremely sensitive spectroscopic detection method allows rapid quantification of organic reactions directly on the resin. © 1999 John Wiley & Sons, Inc. Biotechnol Bioeng (Comb Chem) 61:179–187, 1998/1999.     

The use of optical spectroscopy in combinatorial chemistry.

Infrared and Raman spectroscopy allow direct spectral analysis of the solid-phase, thus avoiding the tedious cleavage of compounds from the solid support. With diagnostic bands in starting materials or products, infrared and Raman spectroscopy are efficient in monitoring each reaction step directly on the solid phase. Consequently, infrared and Raman spectroscopy have evolved as the premier analytical methodology for direct analysis on the solid support. While infrared transmission spectroscopy is a general analytical method for resin samples, internal reflection spectroscopy is especially suited for solid polymer substrates known as "pins" or "crowns." Single bead analysis is done best by infrared microspectroscopy, whereas photoacoustic spectroscopy allows totally nondestructive analysis of resin samples. With an automated accessory, diffuse reflection spectroscopy provides a method for high throughput on-bead monitoring of solid-phase reactions. Providing identification based on molecular structure, HPLC-FTIR is, therefore, complementary to LC-MS. Additionally, Raman spectroscopy as a complement to infrared spectroscopy can be applied to resin samples and-using a Raman microscope-to single beads. Fluorometry as an extremely sensitive spectroscopic detection method allows rapid quantification of organic reactions directly on the resin.     

Monitoring solution-phase combinatorial library synthesis by capillary electrophoresis.

Capillary electrophoresis has been applied to monitor model reactions in solution-phase combinatorial chemistry. In particular, the simultaneous alkylation reactions of secondary amines with a series of benzyl halides has been investigated. Reactant and product concentrations were monitored using capillary electrophoresis in a non-aqueous buffer system. The simplified sample preparation was a key feature making this an attractive method of analysis. The results demonstrate that capillary electrophoresis is a useful tool for monitoring reactions to determine initial rates, rate constants, and extinction correlation coefficients for quantitative analysis in combinatorial chemistry, and is a broadly applicable technique for the analysis of a variety of organic and bioorganic transformations.     

Beyond Rf tagging

The split-pool diversity orientated synthesis method, which requires some form of encoding to track the synthesis of discrete compounds, has been the lynchpin of most combinatorial synthesis efforts. The use of encoding methods in combinatorial chemistry has matured, and depending on their level of resources, chemists now have a diverse choice of encoding methods available. New methods of encoding have been developed that are inexpensive, simple to incorporate into any laboratory, and utilize analytical equipment such as MS, FTIR and NMR that are readily available to most organic chemists.     

Parallel synthesis of potent dopaminergic N-phenyltriazole carboxamides applying a novel click chemistry based phenol linker

Taking advantage of our click chemistry based methodology to construct novel SPOS (solid phase organic synthesis) resins, the triazolylmethyl linked catechol 6a was discovered, which is readily available via copper(I)-catalyzed azide–alkyne cycloaddition (CuAAC) of azidomethyl substituted polystyrene with O-propargylcatechol and can be applied for the parallel synthesis of N-phenyltriazole carboxamides. As a proof-of-concept, a ‘catch-and-release’ strategy could be successfully applied for a parallel synthesis of dopaminergic phenyltriazoles of type 2. A focused model library of 20 test compounds revealing three points of diversity was generated by a three-step SPOS approach. Product purification was performed employing a solid-supported carboxylic acid anhydride as a scavenger. GPCR-ligand binding screening revealed dopamine D3 receptor ligands with K_i values in the single digit nanomolar range.     

Monitoring solution‐phase combinatorial library synthesis by capillary electrophoresis

Capillary electrophoresis has been applied to monitor model reactions in solution‐phase combinatorial chemistry. In particular, the simultaneous alkylation reactions of secondary amines with a series of benzyl halides has been investigated. Reactant and product concentrations were monitored using capillary electrophoresis in a non‐aqueous buffer system. The simplified sample preparation was a key feature making this an attractive method of analysis. The results demonstrate that capillary electrophoresis is a useful tool for monitoring reactions to determine initial rates, rate constants, and extinction correlation coefficients for quantitative analysis in combinatorial chemistry, and is a broadly applicable technique for the analysis of a variety of organic and bioorganic transformations. © 1999 John Wiley & Sons, Inc. Biotechnol Bioeng (Comb Chem) 61:169–177, 1998/1999.     

Online NMR for monitoring biocatalysed reactions

Monitoring biocatalysed reactions and metabolic pathways using NMR spectroscopy is of growing interest. As a non-invasive analytical method providing simultaneous information about intracellular and extracellular constituents, it is superior to other analytical techniques and has a wide range of applications: kinetics and stoichiometrics of metabolic events, metabolic fluxes and enzyme activities can be detected in situ or after taking a sample from the biotransformation mixture. New NMR pulse sequences provide even more valuable experiments in these fields. Research topics range from the monitoring of polymer formation to fermentations producing beverages or antibiotics. Routine monitoring of industrial fermentations by NMR seems to be imminent.     

'One bead two compound libraries' for detecting chemical and biochemical conversions

When combinatorial chemistry was introduced 13 years ago, the expectations were high for the delivery of results, particularly in the pharmaceutical industry. However, combinatorial chemistry was implemented independently of the application for which the products were going to be used. Resins developed only for efficient solid-phase synthesis were used and products were employed in existing assays developed for traditional solution studies. There was almost no assay or technology development and the use of real combinatorial methods soon had to give way to high-throughput synthesis and traditional screening. However, during recent years more sophisticated resins and assay techniques have been developed that may result in a second and more successful implementation of real integrated combinatorial chemistry. The first in this line of new developments is the 'one bead two compound' assay, in which the resin bead in addition to a combinatorial library member contains a reporter compound that can act as a beacon to monitor the activity of the library member. This powerful concept can be generally applied in all fields of combinatorial chemistry including drug, catalysts and material development.     

Carbohydrate and protein immobilization onto solid surfaces by sequential Diels-Alder and azide-alkyne cycloadditions

We demonstrate the applicability of sequential Diels-Alder and azide-alkyne [3 + 2] cycloaddition reactions (click chemistry) for the immobilization of carbohydrates and proteins onto a solid surface. An alpha,omega-poly(ethylene glycol) (PEG) linker carrying alkyne and cyclodiene terminal groups was synthesized and immobilized onto an N-(epsilon-maleimidocaproyl) (EMC)-functionalized glass slide via an aqueous Diels-Alder reaction. In the process, an alkyne-terminated PEGylated surface was provided for the conjugation of azide-containing biomolecules via click chemistry, which proceeded to completion at low temperature and in aqueous solvent. As anticipated, alkyne, azide, cyclodiene, and EMC are independently stable and do not react with common organic reagents nor functional groups in biomolecules. Given an appropriate PEG linker, sequential Diels-Alder and azide-alkyne [3 + 2] cycloaddition reactions provide an effective strategy for the immobilization of a wide range of functionally complex substances onto solid surfaces.     

Serodiagnosis of Lyme borreliosis with bead based immunoassays using multiplex technology

The serological diagnosis of Lyme borreliosis is accomplished by the detection of IgG and IgM antibodies specific for relevant antigens of the spirochetal pathogen Borrelia burgdorferi. Instead of the usual enzyme immune assay for screening and the Western blot technique for confirmation, bead based multiplex assays with multiple simultaneously performed distinct reactions can provide quick, automatically derived and reliable results in a single run by flow cytometer technology. The broad analytical dynamic range of assay signals and the high sensitivity and specificity of the multiplex formats allow even for a reliable use in CSF based analyses for antibody specificity index in supposed neuroborreliosis. Fluorescence intensity of the bead based reactions can be transformed into quantified values as U/ml, either for each single antigen or summed up for a group of relevant key antigens. Additionally or alternatively distinct reactions of single bead populations can be transformed to Western blot band equivalents. Internal and external quality controls with the multiplex systems show characteristic data equivalent to the conventional assay formats, so that the advantages of the multiplex assays are ready for use in the routine diagnostic laboratory.     

Strain-promoted "click" chemistry for terminal labeling of DNA

1,3-Dipolar [3 + 2] cycloaddition between azides and alkynes--an archetypal "click" chemistry--has been used increasingly for the functionalization of nucleic acids. Copper(I)-catalyzed 1,3-dipolar cycloaddition reactions between alkyne-tagged DNA molecules and azides work well, but they require optimization of multiple reagents, and Cu ions are known to mediate DNA cleavage. For many applications, it would be preferable to eliminate the Cu(I) catalyst from these reactions. Here, we describe the solid-phase synthesis and characterization of 5'-dibenzocyclooctyne (DIBO)-modified oligonucleotides, using a new DIBO phosphoramidite, which react with azides via copper-free, strain-promoted alkyne-azide cycloaddition (SPAAC). We found that the DIBO group not only survived the standard acidic and oxidative reactions of solid-phase oligonucleotide synthesis (SPOS), but that it also survived the thermal cycling and standard conditions of the polymerase chain reaction (PCR). As a result, PCR with DIBO-modified primers yielded "clickable" amplicons that could be tagged with azide-modified fluorophores or immobilized on azide-modified surfaces. Given its simplicity, SPAAC on DNA could streamline the bioconjugate chemistry of nucleic acids in a number of modern biotechnologies.     

Preparation of multifunctional nanoparticles and their assemblies

This article describes the synthesis of multifunctional nanoparticulate systems and a range of organic reactions for modifying the surface functionalities of these particles and their composites. The reactions include surface silanization, amine-azide conversion, azide-alkyne 'click' chemistry, thiol and amine click chemistry and amide coupling. In addition, we discuss a number of relevant nanoparticle preparations to exemplify the interrelationship of these reactions. This system can readily be adapted to produce a wide range of composites with different features, such as fluorescence, magnetism, plasmon resonance and multiple biofunctionalities.     

A flexible light-directed DNA chip synthesis gated by deprotection using solution photogenerated acids

Oligonucleotide microarrays or oDNA chips are effective decoding and analytical tools for genomic sequences and are useful for a broad range of applications. Therefore, it is desirable to have synthesis methods of DNA chips that are highly flexible in sequence design and provide high quality and general adoptability. We report herein, DNA microarray synthesis based on a flexible biochip method. Our method simply uses photogenerated acid (PGA) in solution to trigger deprotection of the 5′-OH group in conventional nucleotide phosphoramidite monomers (i.e. PGA-gated deprotection), with the rest of the reactions in the synthesis cycle the same as those used for routine synthesis of oligonucleotides. The complete DNA chip synthesis process is accomplished on a regular DNA synthesizer that is coupled with a UV-VIS projection display unit for performing digital photolithography. Using this method, oDNA chips containing probes of newly discovered genes can be quickly and easily synthesized at high yields in a conventional laboratory setting. Furthermore, the PGA-gated chemistry should be applicable to microarray syntheses of a variety of combinatorial molecules, such as peptides and organic molecules.     

Tetrabutylammonium fluoride-assisted rapid N9-alkylation on purine ring: application to combinatorial reactions in microtiter plates for the discovery of potent sulfotransferase inhibitors in situ

Tremendous efforts have been invested in the synthesis of purine libraries due to their importance in targeting various enzymes involved in different diseases and cellular processes. The synthesis of N9-alkylated purine scaffolds relied mostly on Mitsunobu conditions with a variety of alcohols or strong basic conditions with different organic halides. A more reliable and efficient way for the synthesis of N(9)-alkylated purine scaffolds is reported. This method uses tetrabutylammonium fluoride (TBAF) to assist such chemistry. In many cases, the reactions were completed within 10 min and gave the desired product in high yield and selectivity. Moreover, these mild reaction conditions permitted its use in combinatorial reactions in microtiter plates followed by in situ screening for the discovery of potent sulfotransferase inhibitors.     

Efficient monitoring of enzymatic conjugation reaction by surface-enhanced laser desorption/ionization time of flight mass spectrometry for process optimization

Efficient analysis of bioconjugation reactions is one the most challenging task for optimizing and eventually achieving the reproducible production of large amount of conjugates. In particular, the complexity of some reaction mixtures precludes the use of most of the existing methods, because of the presence of large amounts of contaminants. As an alternative method, we used surface-enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS) for monitoring an in vitro enzymatic transglycosylation of N-acetylgalactosamine (GalNAc) residues to a recombinant mucin protein MUC6. For this reaction, catalyzed by the uridine 5'-diphospho-N-acetylgalactosamine:polypeptide N-acetylgalactosaminyltransferases (ppGalNAc-Ts), we used either a recombinant ppGalNAc-T1 or a mixture of ppGalNAc-Ts contained in MCF7 tumor cell extracts. In the present study, we show that SELDI-TOF MS offers unique advantages over the traditional methodologies. It is a rapid, accurate, sensitive, reproducible, and very convenient analytical method for monitoring the course of a bioconjugation, even in heterogeneous samples such as cell extracts. SELDI-TOF MS proved very useful for optimizing the reaction parameters of the transglycosylation and for achieving the large scale preparation of Tn antigen-glycosylated mucins for antitumor immunotherapy applications.     

Facile Synthesis of Orthogonally Protected Optically Pure Keto- and Diketopiperazine Building Blocks for Combinatorial Chemistry

A simple and convenient synthesis of orthogonally protected multi-tethered, optically pure 2-ketopiperazine and 2,5-diketopiperazine scaffolds for Fmoc and Boc combinatorial chemistry was achieved, starting from accessible chiral amino acid precursors, by sequentially utilizing reductive alkylation, dipeptide coupling and ketopiperazine ring formation as key steps. These scaffolds can introduce valuable drug-like properties in three independent directions to any medicinally relevant piperazine-based motif by “around the scaffold” drug optimization. In addition, these building blocks have a wide application scope in managing fast and efficient multi-cyclic optimization processes in the combinatorial chemistry and drug design fields.     

Peptidic catalysts developed by combinatorial screening methods

In recent years, oligopeptides have been developed as efficient catalysts for a range of important organic reactions, including acylation, silylation, oxidation, ester hydrolysis and aldol reactions. With many peptidic catalysts, high yields and chiral induction can be achieved under mild reaction conditions. Discovery and optimization of these catalysts typically involves the testing of compound collections and is therefore strongly linked to advances in combinatorial screening methods. This review summarizes recent developments in the field of catalytically active short-chain peptides, highlighting the combinatorial techniques that have facilitated their discovery.     

Recognition of neutral species with synthetic receptors

The design of synthetic receptors for neutral molecules is an area of intense current interest. The area has grown from early work on cyclodextrin or single crown ether complexation to encompass a wide array of receptor shapes and structures. Furthermore, the range of substrate selectivities has increased from simple aromatic or metal ion substrates to include key biological components such as peptides and carbohydrates. Recent advances have included the application of split bead combinatorial methods for the identification of receptors for oligopeptides, the design of self-assembling spherical receptors, the use of multiple hydrogen bonding groups for carboxylic acid and carbohydrate recognition and the achievement of impressive catalytic effects with synthetic receptors.     

Temperature-controlled micro-TLC: a versatile green chemistry and fast analytical tool for separation and preliminary screening of steroids fraction from biological and environmental samples

This paper is a continuation of our previous research focusing on development of micro-TLC methodology under temperature-controlled conditions. The main goal of present paper is to demonstrate separation and detection capability of micro-TLC technique involving simple analytical protocols without multi-steps sample pre-purification. One of the advantages of planar chromatography over its column counterpart is that each TLC run can be performed using non-previously used stationary phase. Therefore, it is possible to fractionate or separate complex samples characterized by heavy biological matrix loading. In present studies components of interest, mainly steroids, were isolated from biological samples like fish bile using single pre-treatment steps involving direct organic liquid extraction and/or deproteinization by freeze-drying method. Low-molecular mass compounds with polarity ranging from estetrol to progesterone derived from the environmental samples (lake water, untreated and treated sewage waters) were concentrated using optimized solid-phase extraction (SPE). Specific bands patterns for samples derived from surface water of the Middle Pomerania in northern part of Poland can be easily observed on obtained micro-TLC chromatograms. This approach can be useful as simple and non-expensive complementary method for fast control and screening of treated sewage water discharged by the municipal wastewater treatment plants. Moreover, our experimental results show the potential of micro-TLC as an efficient tool for retention measurements of a wide range of steroids under reversed-phase (RP) chromatographic conditions. These data can be used for further optimalization of SPE or HPLC systems working under RP conditions. Furthermore, we also demonstrated that micro-TLC based analytical approach can be applied as an effective method for the internal standard (IS) substance search. Generally, described methodology can be applied for fast fractionation or screening of the whole range of target substances as well as chemo-taxonomic studies and fingerprinting of complex mixtures, which are present in biological or environmental samples. Due to low consumption of eluent (usually 0.3-1mL/run) mainly composed of water-alcohol binary mixtures, this method can be considered as environmentally friendly and green chemistry focused analytical tool, supplementary to analytical protocols involving column chromatography or planar micro-fluidic devices.     

Mass spectrometric analysis in combinatorial chemistry.

The continuing success of the combinatorial approach is heavily reliant on analytical methodologies, which allow for the rapid and accurate characterisation of medicinally relevant molecules from compound libraries. Mass spectrometry has recently been touted as the most suitable tool for a range of combinatorial applications such as structural elucidation and screening. The refinement of conventional methods, developments of techniques such as Fourier transform ion cyclotron resonance and new screening methodologies have allowed the medicinal chemist to tackle the growing analytical challenges posed by combinatorial chemistry.