Soluble telmisartan and telmisartan were loaded in to poly (ethylene-glycol) grafted chitosan nanoparticles (S-TEL-PEG-CNPs and TEL-PEG-CNPs) for targeting cervical cancer through non-invasive, intravaginal route. The mean particle size of S-TEL-PEG-CNPs was measured to be 23.4±5.9-nm significantly (P<0.05) higher than 16.2±3.2-nm of TEL-PEG-CNPs. In contrast, the zeta-potential (-21.5±4.6-mV) of S-TEL-PEG-CNPs was insignificantly (P>0.05) different from -23.8±3.7-mV of TEL-PEG-CNPs. In addition, S-TEL-PEG-CNPs exhibited higher percent mucoadhesiveness (40.2%) in comparison (P<0.05) to 31.4% of TEL-PEG-CNPs, although it was lower than CNPs (100%). S-TEL-PEG-CNPs displayed significantly (P<0.01) higher dissolution of drug, 92.5% in comparison to 31.6% from TEL-PEG-CNPs up to 24h. Furthermore, S-TEL-PEG-CNPs exhibited superior cytotoxicity, apoptosis and cellular uptake, analyzed in human cervical cancer, HeLa cells. The IC50 of S-TEL-PEG-CNPs was measured to be 22.3-μM significantly (P<0.05) lower than 40.1-μM of TEL-PEG-CNPs. S-TEL-PEG-CNPs induced higher extent of apoptosis (P<0.05) in HeLa cells as compared to TEL-PEG-CNPs, owing to higher diffusion of drug across biological membrane. Finally, quantitative and qualitative cellular uptake assay confirmed the greater endocytosis of S-TEL-PEG-CNPs in HeLa cells due to diffusion, amorphization, hydrophilicity, and submicron size particularly, below 100nm. In conclusion, S-TEL-PEG-CNPs warrant further in vivo tumour regression study to scale up the technology for clinical translation.