Recent Strategies for the Development of Biosourced-Monomers, Oligomers and Polymers-Based Materials: A Review with an Innovation and a Bigger Data Focus

生物材料与纳米技术(英文) Pub Date : 2016-10-21 DOI:10.4236/JBNB.2016.74017

S. Rebouillat, F. Pla

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引用次数: 14

Abstract

After setting the ground of the quantum innovation potential of biosourced entities and outlining the inventive spectrum of adjacent technologies that can derive from those, the current review highlights, with the support of Bigger Data approaches, and a fairly large number of articles, more than 250 and 10,000 patents, the following. It covers an overview of biosourced chemicals and materials, mainly biomonomers, biooligomers and biopolymers; these are produced today in a way that allows reducing the fossil resources depletion and dependency, and obtaining environmentally-friendlier goods in a leaner energy consuming society. A process with a realistic productivity is underlined thanks to the implementation of recent and specifically effective processes where engineered microorganisms are capable to convert natural non-fossil goods, at industrial scale, into fuels and useful high-value chemicals in good yield. Those processes, further detailed, integrate: metabolic engineering involving 1) system biology, 2) synthetic biology and 3) evolutionary engineering. They enable acceptable production yield and productivity, meet the targeted chemical profiles, minimize the consumption of inputs, reduce the production of by-products and further diminish the overall operation costs. As generally admitted the properties of most natural occurring biopolymers (e.g., starch, poly (lactic acid), PHAs.) are often inferior to those of the polymers derived from petroleum; blends and composites, exhibiting improved properties, are now successfully produced. Specific attention is paid to these aspects. Then further evidence is provided to support the important potential and role of products deriving from the biomass in general. The need to enter into the era of Bigger Data, to grow and increase the awareness and multidimensional role and opportunity of biosourcing serves as a conclusion and future prospects. Although providing a large reference database, this review is largely initiatory, therefore not mimicking previous classic reviews but putting them in a multiplying synergistic prospective.

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生物源单体、低聚物和聚合物基材料的最新发展策略:创新和更大的数据焦点综述

在为生物源实体的量子创新潜力奠定了基础，并概述了由此产生的相关技术的发明范围之后，在大数据方法和相当多的文章的支持下，目前的综述强调了超过250项和10,000项专利，如下。它涵盖了生物源化学品和材料的概述，主要是生物单体，生物低聚物和生物聚合物;这些产品的生产方式可以减少对化石资源的消耗和依赖，并在一个更清洁的能源消费社会中获得更环保的产品。由于最近实施了特别有效的工艺，工程微生物能够在工业规模上以高产量将天然非化石产品转化为燃料和有用的高价值化学品，因此强调了具有实际生产力的工艺。这些过程，进一步详细，整合:代谢工程涉及1)系统生物学，2)合成生物学和3)进化工程。它们能够实现可接受的产量和生产率，满足目标化学剖面，最大限度地减少投入物的消耗，减少副产品的产生，并进一步降低总体运营成本。众所周知，大多数天然存在的生物聚合物(如淀粉、聚乳酸、pha)的性能往往不如从石油中提取的聚合物;目前已成功生产出性能得到改善的共混物和复合材料。对这些方面给予了特别的关注。然后提供进一步的证据来支持从一般生物质衍生的产品的重要潜力和作用。需要进入大数据时代，成长和提高生物资源的意识和多维作用和机会，这是一个结论和未来的展望。虽然提供了一个庞大的参考数据库，但这篇综述在很大程度上是初步的，因此不是模仿以前的经典综述，而是将它们放在一个倍增的协同前景中。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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生物材料与纳米技术(英文)

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