The class of hybrid organic−inorganic materials called bridged polysilsesquioxanes are
used for everything from surface modifiers and coatings to catalysts and membrane materials.
This paper examines how bridged polysilsesquioxanes are prepared, processed, characterized,
and used. In particular, it describes how attaching several “inorganic” cross-linking
trialkoxysilanes on organic bridging groups permits facile formation of network polymers
and gels with high levels of chemical functionality. There are a number of synthetic entries
into bridged polysilsesquioxane monomers that have allowed a multitude of different bridging
groups to be integrated into xerogels (dry gels) or aerogels (supercritically dried “air gels”).
Much of the research to date has been successfully focused on engineering of the size of
pores through the choice of the bridging groups. For example, materials with some of the
highest known surface areas in porous materials have been prepared, and parameters
allowing control of the pore size distributions are well understood. More recently, however,
the focus has shifted to building functionality into the bridging groups to make materials
with controlled porosity that are capable of selective adsorption or catalysis or electronic
and optic effects. This is the area where the full potential of bridged polysilsesquioxanes as
molecular-engineered materials is being explored.
A novel method for preparation of biomacromolecular imprinted nanoparticles is described. Combinations of functional monomers were polymerized in the presence of the imprinting peptide melittin in aqueous solution at room temperature to produce a small library of polymer nanoparticles. The template peptide and unreacted monomers are subsequently removed by dialysis. Nanoparticles (NPs) from the library were evaluated for their binding to melittin by 27 MHz QCM analysis. NPs prepared with optimized functional monomer combinations bind strongly to the target molecule. Nanoparticles that were polymerized in the absence of template peptide were found to have little affinity to the peptide. Binding affinity and the size of imprinted particles are comparable to those of natural antibodies. They interact specifically with the target peptide and show little affinity for other proteins. These NPs are of interest as inert and stable substitutes for antibodies. Extension of this approach to other targets of biological importance and the applications of these materials are currently being evaluated.
We report that simple, synthetic organic polymer nanoparticles (NPs) can capture and clear a target peptide toxin in the bloodstream of living mice. The protein-size polymer nanoparticles, with a binding affinity and selectivity comparable to natural antibodies, were prepared by combining a functional monomer optimization strategy with molecular imprinting nanoparticle synthesis. As a result of binding and removal of melittin by NPs in vivo, mortality and peripheral toxic symptoms of melittin were significantly diminished. In vivo imaging of the polymer nanoparticles or "plastic antibodies" establishes the NPs accelerate clearance of the peptide from blood where they accumulate in the liver. Coupled with their biocompatibility and nontoxic characteristics, plastic antibodies offer potential for neutralizing a wide range of biomacromolecules in vivo.In nature, antibodies recognize target molecules by a combination of multiple weak electrostatic, hydrophobic and hydrogen bonding interactions between complementary threedimensional surfaces. To mimic these interactions, nanoparticles (NPs) with affinity for a target peptide or protein have been synthesized by optimizing the composition and ratio of functional groups that make up the NPs.1 , 2 However, the specificity and affinity of the random yhoshino@uci.edu; kjshea@uci.edu. Supporting Information Available: Experimental procedures and supporting data. This material is available free of charge via the Internet at http://pubs.acs.org. We have developed methods for synthesizing protein-size polymer particles with a binding affinity and selectivity comparable to natural antibodies by combining molecular imprinting nanoparticle synthesis with a functional monomer optimization strategy (Figure 1).9 The first stage of this process involves screening small libraries of NPs that span a compositional space chosen for its complementarity to the biological target. 2 The affinity of each NP to the biological target is evaluated and the composition of subsequent NP generations is adjusted to enhance specificity. At the final stage the optimized combination and ratio of functional monomers are polymerized in the presence of the imprinting biological target (peptide or epitope). 9 Following extensive dialysis, polymer NPs exhibit binding affinity, selectivity and particle size comparable to natural antibodies in vitro.
NIH Public AccessAlthough molecular recognition by imprinted materials has been extensively studied in controlled settings, little is reported about their application in the bloodstream of living animals. 10 It is well known that the performance (affinity, specificity and function) of synthetic materials when introduced into a complex biological milieu can be profoundly compromised. Introduction of foreign substances including synthetic NPs into the bloodstream results in the immediate formation of a "corona" of proteins on the surface that can alter and/or suppress the intended function of the NP. 11 Further complications can arise fron an immunogenic re...
A multifunctional and high-efficiency microfluidic device for droplet generation and fusion is presented. Through unique design of the micro-channels, the device is able to alternately generate droplets, generating droplet ratios ranging from 1 ratio 5 to 5 ratio 1, and fuse droplets, enabling precise chemical reactions in several picoliters on a single chip. The controlled fusion is managed by passive control based on the channel geometry and liquid phase flow. The synthesis of CdS nanoparticles utilizing each fused droplet as a microreactor for rapid and efficient mixing of reagents is demonstrated in this paper. Following alternating droplet generation, the channel geometry allows the exclusive fusion of alternate droplets with concomitant rapid mixing and produces supersaturated solution of Cd2+ and S2- ions to form CdS nanoparticles in each fused droplet. The spectroscopic properties of the CdS nanoparticles produced by this method are compared with CdS prepared by bulk mixing.
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