December 22, 2024
Sadegh Karimi

Sadegh Karimi

Academic Rank: Associate professor
Address: Department of Chemistry, Faculty of Nano, Bioscience and Technology
Degree: Ph.D in Chemistry
Phone: 07731222074
Faculty: Faculty of Nano and Biotechnology

Research

Title Hollow mesoporous silica nanoparticles: Effective silica etching using tri-di- and mono-valent cations
Type Article
Keywords
Hollow Mesoporous Silica Nano particles; selective etching; BET; drug loading
Journal Materials Science and Engineering: C Materials for Biological Applications
DOI http://dx.doi.org/10.1016/j.msec.2021.112621
Researchers Maria Dolores Marcos (Third researcher) , Ramón Martínez-Máñez (Fourth researcher) , Sadegh Karimi (Fifth researcher)

Abstract

Among different hollow nanostructures, the preparation of hollow mesoporous silica nanoparticles (HMSNs) is still a hotspot research field due to their unique properties e.g., large pore sizes and volumes, high drug loading capacity, ease of surface modification, large surface area, and biodegradability. Herein, novel uniform HMSNs are prepared for the first time by a combination of heterogeneous oil-water biphase stratification and simple mono-, di-, and tri- valent etching reactions. The biphase stratification reaction allows self-assembly of reactants at the oil−water inter- face, while the subsequent step is designed for the efficient selective silica etching under mild conditions. We have studied the effect of cation's valence (NH4+ , Ca2+ , and Al3+ ) on the silica etching reaction coupled with the biphase stratification reaction both in the absence and presence of the auxiliary pore expanded agent 1, 3, 5 trimethylbenzene (TMB). In the absence of TMB, the Brunauer–Emmett–Teller (BET) analysis confirms that Al3+ creates materials with the largest pore size (18.0 nm), whereas the use of NH4+ results in the largest pore volume (2.30 cm3 /g). The pores gen- erated using Ca2+ and Al3+ as silica etching agents have a volume 2.01 cm3 /g and 2.05 cm3 /g, respectively. Similar experiments in the presence of TMB leads to the formation of HMSN with larger pore sizes (24 nm and 21.5 nm) and volumes (2.70 cm3 /g and 2.12 cm3 /g) when using Al3+ and Ca2+ , respectively, as etching agents. Drug loading capac- ity using Langmuir adsorption model indicate our hollow MSN material exhibit the high adsorbing DOX up to 558.23 mg per gram of nanoparticles in pH of 7.2. Furthermore, synthetized NPs exhibited high loading capacity for large protein and biomolecules such as BSA. Our findings confirmed that the charge density of cation has a critical role on selective silica etching in the preparation of HMSNs