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Nanoreactors for Reaction Cascades
August 21, 2007Living cells are highly complex synthetic machines: Numerous multistep reactions run simultaneously side by side and with unbelievable efficiency and specificity. For these mainly enzymatic reactions to work so well collectively, nature makes use of a variety of concepts. One of the most important of these is division into compartments. Enzymes are not only separated spatially, but also positioned in specific locations within the cell. Researchers from the Netherlands, led by Jan C. M. van Hest and Alan E. Rowan, have now developed an approach to copy this idea, as they report in the journal Angewandte Chemie. They constructed nanoreactors by controlled positioning of two different enzymes in the central water reservoir or the plastic membrane of synthetic nanoscopic bubbles. In combination with a third enzyme in the surrounding solution, this system has made it possible to run three different enzymatic reactions simultaneously, without interference, in a "one-pot" reaction.
To mimic a cellular environment, the scientists produced nanoscopic bubbles surrounded by a membrane made of a special plastic. The plastic is a block copolymer that is analogous to a lipid, the natural building block of cell membranes, in its structure, with a water-friendly "head" and a water-repellent "tail". In analogy to liposomes, which are made from lipids, these bubbles are called polymersomes. Thanks to nearly limitless possibilities in the production of these plastic membranes, the spectrum of properties displayed by polymersomes can be precisely tailored.
The researchers produced their polymersomes such that they let small molecules pass through while forming a barrier to larger ones. This allows enzymes to be trapped inside the polymersomes (in the water reservoir) while the smaller substrate or product molecules pass through unhindered.
To demonstrate the potential of their "nanoreactors", the researchers bound the enzyme horseradish peroxidase into the membrane itself. Within the water reservoir, they trapped the enzyme glucose oxidase. The surrounding solution contained the enzyme lipase B. Glucose molecules with four acetyl groups attached were added as the substrate. In the first step, the lipase B split off the acetyl groups. The resulting glucose could cross the membrane, where it encountered the glucose oxidase and was oxidized by it. This reaction formed hydrogen peroxide, which is just what the horseradish peroxidase was waiting for in order to convert the sample substrate ABTS (2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonic acid))-also contained in the solution-into its radical cation.
Durham University
To demonstrate the potential of their "nanoreactors", the researchers bound the enzyme horseradish peroxidase into the membrane itself. Within the water reservoir, they trapped the enzyme glucose oxidase. The surrounding solution contained the enzyme lipase B. Glucose molecules with four acetyl groups attached were added as the substrate. In the first step, the lipase B split off the acetyl groups. The resulting glucose could cross the membrane, where it encountered the glucose oxidase and was oxidized by it. This reaction formed hydrogen peroxide, which is just what the horseradish peroxidase was waiting for in order to convert the sample substrate ABTS (2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonic acid))-also contained in the solution-into its radical cation.
Durham University
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Nanoreactor Engineering for Life Sciences and Medicine (Artech House Series Engineering in Medicine & Biology) by Agnes Ostafin (Editor), Katharina Landfester (Editor) Nanoreactors are nanoscale vehicles for enzymes and sensors that are used to create physical and chemical reactions. Nanoreactor developers are on the cusp of extraordinary advances in medical diagnostics and therapies, tissue engineering, and cell biology, and this authoritative resource puts bioengineers right at the cutting edge. This unique book offers first-of-its-kind coverage of nanoreactor design, providing full details on the research, practice, synthesis, and characterization of nanoreactors. It includes 14 actual systems explained by the pioneers who are developing them. This groundbreaking volume reviews the fundamentals of various nanoreactor configurations and addresses core design issues and challenges. |
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Nano-reactors for controlling the selectivity of the free radical grafting of maleic anhydride onto polypropylene in the melt.: An article from: Polymer Engineering and Science by Dean Shi (Author), R.K.Y. Li (Author), Yutian Zhu (Author), Zhuo Ke (Author), Jinghua Yin (Author), Wei Jiang (Author), Guo-Hua Hu (Author) This digital document is an article from Polymer Engineering and Science, published by Thomson Gale on October 1, 2006. The length of the article is 7419 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. From the author: This paper reports on a successful application of the concept of nanoreactors to effectively controlling the selectivity of the free radical grafting of maleic anhydride (MAH) onto polypropylene (PP) in the melt, an industrially relevant process. More specifically, a free radical initiator of type ROOR was first confined into (or encapsulated by) the galleries of an organically modified... |
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