Fragmentation organic chemistry

Organic chemists have been aware of reversible addition-fragmentation involving xanthate esters in organic chemistry for some time. It is the basis of the Barton-McCombie process for deoxygenation of alcohols (Scheme 9.37).402 404... 

The selection of the thirty procedures clearly reflects the current interest of synthetic organic chemistry. Thus seven of them illustrate uses of T1(I), T1 (III), Cu(I), and Li(I), and three examples elaborate on the process now termed phase-transfer catalysis. In addition, newly developed methods involving fragmentation, sulfide contraction, and synthetically useful free radical cyclization arc covered in five procedures. Inclusion of preparations and uses of five theoretically interesting compounds demonstrates the rapid expansion of this particular area in recent years and will render these compounds more readily and consistently available. 

A complete structural analysis can sometimes be accomplished by a study of the fragmentation pattern. Some general rules for the modes of fragmentation expected from particular types of compound are formulated on the basis of the concepts of physical and organic chemistry. These are ... 

The fragmentation may occur due to favorable delocalization of the unpaired electron in the neutral particle forming. Again the rules of classic organic chemistry... 

Ortho-Effect. The ortho-effect is one of the most widely known structural phenomena in organic chemistry. It is widely used in organic chemistry for synthetic purposes. The mass spectra of the majority of ort/jo-substituted aromatic compounds possess significant differences in comparison with the spectra of their meta- and para-isomers. A classic example of the ortho-effect in mass spectrometry involves fragmentation of alkylsalicylates. The intense peaks of [M - ROH]+ ions dominate in the El spectra of these compounds. These peaks are absent in the spectra of their meta- and para-isomers. The reaction leading to these ions may be represented by Scheme 5.12. 

Radical chemistry has seen tremendous progress in the past two decades and can now be considered as an eminent sub discipline in synthetic organic chemistry [1-6]. Diastereoselective radical chemistry is well established and many examples of enantioselective radical reactions have appeared in the recent literature. For reviews on diastereoselective radical chemistry see [7-11] for reviews on enantioselective radical chemistry see [12-16] and for reviews on conjugate additions, see [17,18]. This review will detail different ways to introduce asymmetry during a radical reaction. These transformations can be broadly classified into atom transfer reactions, reductive alkylations, fragmentations, addition and trapping experiments, and electron transfer reactions. 

Nowadays, solid-phase synthesis has been used as a powerful tool in organic chemistry, especially to prepare small molecule libraries. New linkers to obtain different functionalities after cleavage have been developed. There are different linkers strategies (Fig. 3.2), for example traceless linkers, multifunctional linkers, safety catch linkers, fragmentation/ cycloreversion cleavage linkers, cyclization cleavage linkers, which are useful methods for combinatorial solid-phase chemistry. 

As fragmentation reactions in a mass spectrometer involve the breaking of bonds, they can be represented by the standard "arrow notation" used in organic chemistry. For some purposes a radical cation e.g. a generalised ion of the molecular ion) can be represented without attempting to localise the missing electron ... 

The use of polylithium synthons in synthetic organic chemistry presents the advantage of making possible the simultaneous introduction of various electrophilic fragments in the reaction with electrophiles, in such a way that polyfunctionalized molecules can be directly prepared. 

Organic chemistry as a subject fragments—synthetic and Natural Products... 

In organic chemistry, elimination processes are those decompositions of molecules whereby two fragments are split off and the multiplicity of the bonds between two carbon atoms or a carbon atom and a hetero atom is increased. Such a broad definition also embraces the dehydrogenation of hydrocarbons and alcohols which is dealt with in Chap. 2. Here we shall restrict our review to the olefin-forming eliminations of the type... 

Fragmentation Reactions Aspects Mainly from Synthetic Organic Chemistry T. Wakabay-ashi and K. Watanabe, Yuki Gosei Kagaku Kyokaishi, 1980, 38, 853-861. Nucleophilic Eliminative Ring Fission C. J. M. Stirling, Chem. Rev., 1978, 78, 517-567. 

Since many metal fragments are isolobal with CH2, it should be possible to make a range of metallacycloalkanes. Metallacyclobutanes are well known as a class of compounds and serve as key intermediates in catalytic alkene metathesis.1 This reaction has gained great importance in recent years through the work of Grubbs2 and Schrock.3 Alkene metathesis has many applications in organic chemistry,... 

Isocyanides, formal divalent carbon functionalities, are ideal candidates for the development of MCRs. Their reaction with carbonyls and imines, through an a-addition process, generates a zwitterionic intermediate, which is then trapped by a nucleophile. The resulting double a-addition adduct is unstable and rapidly undergoes the Mumm rearrangement to afford the final product (Scheme 12.32). The venerable three-component Passerini reaction is the first MCR based on this type of reaction process [116]. It addresses the formation of a-acyloxycarboxamides, which constitute a class of very versatile synthons in organic chemistry. In the present context, this reaction was utilized by Schmidt and collaborators for the elaboration of intermediate 234 [117], a key fragment for the synthesis of the prolyl endopeptidase inhibitor Eurystatin A 231 (Scheme 12.33) [118]. 

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