Synthesis of Porous Silica with Hierarchical Structure Directed by a Silica Precursor Carrying a Pore-Generating Cage

We have obtained a new class of porous silica with good structural order and additional corrugated nanopores clustered around the primary mesopores from the co-condensation of TEOS and adamantylphenol-grafted trimethoxysilane (adam-graft SQ) using a triblock Pluronic P123 (EO20PO70EO20,Mw = 5800) copolymer as a structure-directing agent. Thermally activated removal of pore-generating moieties (i.e., adamantylphenol groups) in adam-graft SQ involves the generation of secondary micro-to-small mesopores, while the block copolymer template generates 2D-hexagonal mesopores. We found that the mesostructural characteristics and the generation of secondary indented pores right next to the mesopores can be tailored by the addition order of the two silica precursors (TEOS and adam-graft SQ), varying the molar ratio between TEOS and adam-graft SQ in the starting sol mixture, and the degree of silica polymerization. The increase in the hexagonal unit cell parameters is attributed to the increment of pore size originating from the removal of adamantylphenol moieties. It is believed that the hydrophobicity of adamantylphenol groups plays a key role in its selective incorporation into the region near the PPO core blocks and the subsequent generation of corrugated pores along the silica channels resulting in the increase of pore diameter.This work was financially supported by the Korea Science and Engineering Foundation (KOSEF) grant through the Acceleration Research Program (R17-2007-059-01000-0) and the NANO Systems Institute – National Core Research Center (R15-2003-032-02002-0) funded by the Ministry of Education, Science and Technology (MEST) and the Brain Korea 21 Program endorsed by the MEST. Financial support from the Korean Collaborative Project for Excellence in Basic System IC Technology (System IC 2010) is also greatly acknowledged

Targeted Binding of the M13 Bacteriophage to Thiamethoxam Organic Crystals

Phage display screening with a combinatorial library was used to identify M13-type bacteriophages that express peptides with selective binding to organic crystals of thiamethoxam. The six most strongly binding phages exhibit at least 1000 times the binding affinity of wild-type M13 and express heptapeptide sequences that are rich in hydrophobic, hydrogen-bonding amino acids and proline. Among the peptide sequences identified, M13 displaying the pIII domain heptapeptide ASTLPKA exhibits the strongest binding to thiamethoxam in competitive binding assays. Electron and confocal microscopy confirm the specific binding affinity of ASTLPKA to thiamethoxam. Using atomic force microscope (AFM) probes functionalized with ASTLPKA expressing phage, we found that the average adhesion force between the bacteriophage and a thiamethoxam surface is 1.47 ± 0.80 nN whereas the adhesion force of wild-type M13KE phage is 0.18 ± 0.07 nN. Such a strongly binding bacteriophage could be used to modify the surface chemistry of thiamethoxam crystals and other organic solids with a high degree of specificity

Controlling the Morphology of Organic Crystals with Filamentous Bacteriophages

The preparation of thiamethoxam (TMX) organic crystals with high morphological uniformity was achieved by controlled aggregation-driven crystallization of primitive TMX crystals and phage using the filamentous M13 bacteriophage. The development of a regular, micrometer-sized, tetragonal-bipyramidal crystal structure was dependent on the amount of phage present. The phage appears to affect the supersaturation driving force for crystallization. The phage adsorption isotherm to TMX was well-fitted by the Satake–Yang model, which suggests a cooperative binding between neighboring phages as well as a binding of phage with the TMX crystal surface. This study shows the potential of phage additives to control the morphology and morphological uniformity of organic crystals