1. Compared with commercial SPE adsorbents, MIP-IL@UiO-66 exhibited better adsorption performance. Then the MISPE column based on MIP-IL@UiO-66 was built and combined with high-performance liquid chromatography (HPLC) to absorb and sense sulfamethoxazole in pork, egg, soil, and water samples, satisfactory recoveries of 91-106% were obtained. Ahmadijokani et al. used a well-known stable UiO-66 MOF for cationic and anionic dye removal from aqueous solutions [81]. Through a series of experimental characterizations, pristine UiO-66 showed outstanding structural stability against DMF, chloroform, and water. The adsorption capacity was 384 mg/g for methyl red, 454 mg/g for methyl orange, 133 mg/g for malachite green, and 370 mg/g for methylene blue, and the partition coefficients were 1.137, 2.208, 0.070, and 1.345 mg/g �M, respectively. The excellent absorption capability can be attributed to the physical adsorption, ?-? stacking interaction, hydrogen bonding, electrostatic interaction, and porous capture. Furthermore, UiO-66 nanoparticles aged in water exhibited a larger propensity to adsorb anionic methyl red and methyl orange than cationic malachite green, mainly because of the electrostatic attractions therein. Yu et al. produced a chemically stable Zr(IV)-based MOF (BUT-17) for simultaneous adsorption and determination of bisphenol compounds (BPs) [82]. At first, the generated BUT-17 had a large surface area of 2936 m 2 /g, which can achieve efficient and rapid adsorption of BPs with an adsorption capacity of 111 mg/g and an adsorption rate of 1.76 g/mg/min;MIP-IL@UiO-66 had the advantages of excellent adsorption selectivity (selectivity coefficient, 11.36), ultrafast equilibrium rate (equilibrium time, 10 min), good reusability (number of cycles, five times), and large adsorption capability (maximum capacity

2. Supramolecular control of mof pore properties for the tailored guest adsorption/separation applications;D Wu;Coord. Chem. Rev,2021

3. Metal-organic frameworks as photoluminescent biosensing platforms: Mechanisms and applications;Y Zhao;Chem. Soc. Rev,2021

4. Boosting catalysis of pd nanoparticles in MOFs by pore wall engineering: The roles of electron transfer and adsorption energy;D Chen;Adv. Mater,2020

5. A tailor-made interpenetrated MOF with exceptional carbon-capture performance from flue gas;W Liang;Chem,2019