α-Galactosylceramide (α-GalCer), a glycolipid derived from marine sponge, found to exhibit antitumor activity in vitro and in vivo. Upon binding with CD1d molecule on APC, this CD1d/glycolipid/NKT cell complex stimulates the production of both Th1 and Th2 cytokines by NKT cells. Aromatic acyl chain modifications and aromatic substituents on ceramide and galactose C6” of α-GalCer, respectively, were found to exhibit potent agonistic activity to Th1 cytokines secretions. The structure-activity relationship (SAR) study of the substitutions on both aromatic rings has not yet been reported. Base on Topliss rule, we designed various phenyl-substituted acyl chain analogs of α-GalCer and evaluated their IL-2 secretion in A20CD1d & mNK1.2 system. Compounds with different aromatic substitutions on undecanoyl chain were shown to have comparable activity to α-GalCer. The C6” phenyl acetamido substituted analog 87 was the most potent one among 87 - 89. Furthermore, the C6” and acyl chain bi-modified analogs were synthesized and evaluated, compounds with electron-donating property (94, 98, 100) at C6” phenyl acetamido group were found to slightly increase immunostimulating activity compared to α-GalCer. The most potent α-GalCer analog, C34, was chosen for preclinical and clinical application for anticancer therapy. Although milligram-scale syntheses of glycolipids have been developed for medicinal chemical research, a large scale synthesis and process development have not been reported. To this end, we developed a scale-up synthesis of C34 in an eight-step process commenced from phytosphingosine HCl in total 14% yield. The critical step of this process is glycosylation, thiolglycoside was selected as a glycosyl donor which was activated by Me2S2-Tf2O under mild condition. Such strategy is more applicable in industrial practice. After each step was fine tuned and optimized, we were able to operate up to 50 g scale in the laboratorial batch.