Activated alkenes (I) containing electron-withdrawing group are used for the synthetic organic transformations in this thesis. At first, when R1 is benzoyl group, in situ formed phosphonium salts resulted from I, tributylphosphine, and acyl chlorides are deprotonated by triethylamine to provide multisubstituted furans II. When R is CO2Et and R1 is hydrogen, alkenes I react with tributylphosphine and various aldehydes to afford highly functionalized alkenes III. When R and R1 are hydrogen, the reactions of alkenes I, aldehydes or imines, and the corresponding nucleophiles catalyzed by ethyl diphenylphosphine or triphenylphosphine proceed successfully to furnish the multi-functional adducts IV. Finally, alkenes I can also undergo asymmetric, organocatalytic Michael additions with cyclohexanone catalyzed by chiral secondary amine to yield the highly functional products V with high stereoselectivities.