Mass spectrometric screening of catalysts

Chemistry: analytical and immunological testing – Testing of catalyst

Reexamination Certificate

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C250S281000, C250S282000, C250S288000, C436S173000

Reexamination Certificate

active

06797516

ABSTRACT:

BACKGROUND OF THE INVENTION
Described here is a rapid screening method for identifying compounds having catalyst activity which employs mass spectrometric analysis. The method is exemplified for rapid screening of polymerization catalysts using tandem mass spectrometry and gas phase ion-molecule reactions and is specifically applied to screening of organometallic catalysts used in the production of polyolefins. The screening method of this invention has the advantages of high sensitivity (mg-scale quantities), very short assay times (one hour), simultaneous competitive screening of multiple catalysts directly according to propensity for high polymer formation (rather than a derivative property such as heat release), good prospects for scaling to large combinatorial libraries, and implicit encoding of catalyst identity by mass. Simple ion-molecule reactions are used to simplify the mass spectrum of complicated mixtures generated during screening.
The identification, preparation and testing of individual catalysts has been long pursued. The screening of catalyst libraries to identify new and improved catalysts is a recent phenomenon. Screening of libraries of compounds, which may have been combinatorially generated, has been extensively applied in biological systems and for the identification of potential therapeutic agents. Methods for high-throughput combinatorial screening of organometallic catalysts now occupy a central position in the emerging area of combinatorial materials science. (A general review of screening for catalysts has recently appeared: Jandeleit, B. et al. (1998) Cat. Tech. 2:101). A variety of strategies have been employed to implement catalyst screening by correlating some aspect of catalysis to a measurable quantity. Preferred screening strategies are those that are rapid and which can be applied to assess very small samples. Chromatographic (Francis, M. B. (1999) Angew. Chem. 111:987), thermographic (Taylor, S. J. and Morken, J. P. (1998) Science, 280:267; Reetz, M. T. et al. (1998) Angew Chem. 110:2792), fluorescence quenching (Cooper, A. C. et al. (1998) J. Am. Chem. Soc. 120:9971), microwell parallel reactions (Burgess, K. et al. (1996) Angew. Chem. 108:192; Senkan, S.M. (1998) Nature 394:350), and polymer-supported “Bead” methods (Cole, B. M. et al. (1996) Angew. Chem. 108:1776; Boussie, T. R. et al. (1998) Angew. Chem. 110:3472) have been applied with varying degrees of success. Only the polymer-supported bead methods have been applied to identify organometallic catalysts for polymerization reactions, the other methods being inapplicable for a variety of technical reasons. Even the polymer-supported bead method, when applied to polyolefin catalyst screening, suffers from a clumsy encoding procedure that limits its usefulness.
Catalyst screening strategies typically assay reaction rate or turnover number by rapid assay of the products of a catalyzed reaction. The emphasis is on the miniaturization and acceleration of methods used conventionally for product determination. For example, rate is correlated with heat release in the thermographic assay, which is appropriate for assays of overall catalytic activity. For polymerization reaction catalysts (Recent advances in new homogeneous Ziegler-Natta catalysts have been reviewed: Britovsek, G. J. P. et al. (1999) Angew. Chem. 111:448), on the other hand, overall catalytic activity is only one of several important catalyst properties for which high-throughput screens are needed. The key properties of polymerization products: average molecular weight (M
w
, the weight-average molecular weight, or M
n
, the number-average molecular weight) and molecular weight distribution (M
w
/M
n
, a measure of polydispersity because M
w
emphasizes the heavier chains, while M
n
emphasizes the lighter ones) are currently not accessible in any fast assay. The usual methods used to assess these properties of polymers, e.g., size-exclusion chromatography (also termed gel permeation chromatography or gpc), light scattering, viscosity, or colligative property measurement, require bulk samples and/or careful calibration, and are poorly suited to high-throughput screening.
SUMMARY OF THE INVENTION
The present invention provides methods for screening catalysts using mass spectrometric analysis of catalyst-bound intermediates in the catalytic cycle, or products of catalysis. The methods are applicable, in particular, to screening of organometallic compounds for catalytic function. Moreover, the methods are applicable, in particular, to screening for catalysts for polymerization reactions. More specifically, the methods employ a two stage (or two step) mass spectrometric detection method in which ions formed in a first stage ionization and which are linked to catalyst performance are selected and the catalyst associated with the selected ion is identified in a second stage employing tandem mass spectrometry. In specific embodiments, the screening methods of this invention avoid explicit encoding because the identity of the catalyst is implicitly contained in the product molecular mass (typically an intermediate product), since the catalyst (or a portion thereof) remains attached to the product.
The methods of this invention are particularly beneficial in screening for polymerization catalysts to avoid spectral congestion that can be created by the distribution of product oligomer and polymer lengths even for analysis of the polymerization products of a single catalyst species. Further, the screen, as applied to polymerization catalysts, is direct in that it assays polymer chain growth itself rather than a property which may be correlated with chain growth.
In the methods of this invention, one or more test catalysts are provided. The test catalysts are contacted with a selected reactant species under selected reaction conditions. The reagent species is a compound or mixture of compounds upon which the catalyst acts to generate a desired product. Reaction conditions are selected to promote a selected catalytic reaction. The catalytic reaction is quenched after a selected time sufficient to allow the selected reaction to proceed to generate product, e.g., for polymer chains to grow, and allow differentiation of catalyst activity. After quenching, the reaction mixture is introduced into the first stage of a tandem mass spectrometer, subjected to ionization, and mass analysis. Prior to introduction into the mass spectrometer, the quenched reaction mixture can optionally be subjected to partial purification, solvent removal, dilution, concentration, or chemical derivatization to improve analysis, remove impurities or the like.
Certain ions formed in the first stage of the tandem mass spectrometer are selected for introduction into the second stage of the spectrometer. Ions are selected which derive from the catalyst activity that is being screened. For example, in screens for polymerization catalysts ion mass selection can be employed, i.e. ions with mass/charge ratio (m/z) greater than a selected cutoff mass can be selected as derived from the best catalysts, e.g., those that promote the longest chains in the time given. The selected ions are introduced into the second stage of the mass spectrometer where they are subjected to a reaction to give daughter ions that allow identification of the catalyst which catalyzed formation of the products whose ions were selected from the first stage. For example, again in polymerization reactions, the selected high mass ions, associated with the longest polymer chains formed, are subjected in the second stage to reactive collisions with neutrals to generate daughter ions. Ion-molecule reactions, including collision-induced dissociation, can be employed to generate daughter ions. Preferred ion molecule reactions are those which cleave the product, e.g., the polymer chain, from its associated catalyst or portion of the catalyst, leaving an ion that can be directly, and preferably, uniquely related to the catalyst. Mass analysis of the daughter ions generated allows identification of the catalyst spe

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