The object of this research is to study the modification and applications of Nanoscale Silicate Platelets (NSP) that were previously prepared from the exfoliation of naturally occurring clays. The silicate platelets were allowed to tether linkers through covalent bonding with the estimated number of 18,000 ≡Si–O-Na+ sites and 100,000-300,000 siloxanol functionalities (≡Si–OH) per platelet. The silicate platelets were then modified by grafting the linker, dimethyl succinate, via transesterification to afford NSP–DMS. The second method is to use sol–gel reaction with tetraethyl orthosilicate as the linker to form NSP–TEOS. Both of NSP–DMS and NSP–TEOS were characterized by using thermogravimetric analysis, silicon nuclear magnetic resonance, and transmission electron microscopy. The two NSP–linkers were used to blend into a typical formulation of acrylic resins. The effectiveness for enhancing hardness of the resultant films while maintaining the excellent transparency was achieved. According to the previous works of small molecule tethering, we further established the NSP tethering with a macromolecule, such as lysozyme, through an amide functionality. The NSP–lysozyme conjugate was also characterized by using thermogravimetric analysis. During the testing for the lysozyme activity, a serendipity was found for the NSP strongly interacting with an enzyme and actually deactivating the biomaterial’s normal function of antimicrobial ability. The finding was observed in both of NSP physical blending and covalently bonding with the lysozyme enzyme. The finding has the implications of designing new method of protein fixation.