Electrophilic reagents, solid supported

Kaldor [49 i, 55] demonstrated the advantages of applying solid-supported scavengers to the preparation of parallel arrays in a multi-step fashion. In these studies he examined the clean-up of multiple amine alkylation and acylation reactions using a variety of immobilized electrophilic and nucleophilic scavenger reagents including an amine, isocyanate, aldehyde and acid chloride (Tab. 2.1). 

Recently, the semi-synthesis of Vancomycin (48) on solid supports was accomplished using an allylic linker (Scheme 3.2) [123, 124]. Polymer-bound chiral electrophilic selenium reagents have been developed and applied to stereoselective se-lenylation reactions of various alkenes (Tab. 3.9) [125]. 

The concept of selective sequestration of non-product species was first demonstrated using solid-supported scavengers with electrophilic and nucleophilic character in amine acylation, amine alkylation, and reductive amination protocols [46]. Since then, a wide range of scavenger reagents has become commercially available from various suppliers. The structures and functions of these scavenger resins are shown in Table 1. 

Silica gel is also the support of choice for the activation of V-halosuccinimides. The silica functions both as a proton donor which increases the electrophilic nature of the reagent, and as a support with geometrical constraints which contributes to the stereoselectivity. Alkyl and aryl sulfoxides are readily halogenated at the a position with yields of48-80%91. The reactions are carried in the solid state on the surface of TLC plates. The conversion of the optically active alkyl 4-methylphenyl sulfoxide into 1-haloalkyl 4-methylphenyl sulfoxide is accompanied by inversion of configuration at the S-atom. The stereoselectivity in these reactions is much higher than that observed in liquid-phase halogenation. 

Some interesting procedures are being developed to make the present protocol more useful as a synthetic tool. Directing to the combinatorial synthesis, solid-phase syntheses have currently been under development using polymer-supported stannanes (Scheme 69) [263-268] or electrophiles (Scheme 70, Scheme 71) [149, 269-272]. In the latter case, unreacted organotin reagent as... 

The purification problem in the solution-phase synthesis of combinatorial libraries is addressed in various ways. For example, for a multistep synthesis polymer-bound reagents could be used [72-75]. A complementary approach uses scavenger, such as a solid-phase-supported electrophile or nucleophile, to remove unreacted starting material after the synthesis has taken place [76-79],... 

Solid-phase scavenger methods are employed with increasing frequency as a prehminary reaction cleanup step in combinatorial chemistry, and have recently become commercially available (Argonaut, Calbiochem-Novabiochem, Varian, Alltech). lilly researchers first reported on this approach, employing sohd supported electrophiles and nucleophiles for reaction purification in acylation and alkylation reactions. Yield and purity values reported were 90-95% and 50-99%, respectively, for a library generated by reductive amination. Parke-Davis researchers achieved the removal of known reaction product impurities by the application of custom synthesized polymer supported reagents, specifically polystyrene-divinylbenzene supported derivatives of methylisocyanate and tm(2-aminomethyl)amine for cleanup of by-products resulting from urea, thiourea,sulfonamide,amide, and pyrazole libraries. 

---