Abstract In this study, a BPA-imprinted organic-inorganic hybrid, which exhibits high adsorption and recognition capability, was successfully fabricated by using polymerization and sol-gel processes. Rigidity of inorganic framework improves imprinting extend. In addition, flexible organic moiety allows high mass transfer in the imprinted polymer. Tetraethyl orthosilicate (TEOS) and 3-(methacryloyloxy)propyl trimethoxysilane (MEMO) were used as the inorganic and organic cross linkers, respectively, and an optimal TEOS-to-MEMO molar ratio for the highest adsorption capacity was 15:10. TGA analysis indicates that the imprinted polymer contains equal mass in the organic and inorganic components. Almost 100% imprinted molecules were extracted from the imprinted matrix to leave a high quantity of available sites (1.881020 /g) for rebinding the target. The maximum binding capacity, which was calculated from Langmuir model, was 65.8 mg/g. The 29Si and 13C NMR spectra reveal that the BPA molecules were imprinted into the cavities in terms of formation of Si-O-C covalent bonding. A high level of imprinting led to a imprinting factor (α) of 2.5, and resulted in the selectivity factor (β) of 78.2, 11.5, 2.3 and infinity for Phenol, Bis(2-hydroxyphenyl)methane (2HDPM), 4-tert-butylphenol (4TBP) and 17β- Estradiol (E2) analogues, respectively. Moreover, the separation factor (s) for phenol and 4TBP was 31.8 and 3.9, respectively, in the HPLC column test. Recoverability of the hybrid shows a small relative standard deviation of 3.9% reveling a high stability of imprinted cavities. These results in this study clearly indicate that the hybrid exhibits outstanding adsorption and recognition performance, which is highly promising for the applications in separation, chromatography and sensing.