Engineering serendipity: High-throughput discovery of materials that resist bacterial attachment

Magennis E. P.; Hook A. L.; Davies M. C.; Alexander C.; Williams P.; Alexander M. R.

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Engineering serendipity: High-throughput discovery of materials that resist bacterial attachment

机译：工程学上的意外发现：高通量发现抗细菌附着的材料

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Controlling the colonisation of materials by microorganisms is important in a wide range of industries and clinical settings. To date, the underlying mechanisms that govern the interactions of bacteria with material surfaces remain poorly understood, limiting the ab initio design and engineering of biomaterials to control bacterial attachment. Combinatorial approaches involving high-throughput screening have emerged as key tools for identifying materials to control bacterial attachment. The hundreds of different materials assessed using these methods can be carried out with the aid of computational modelling. This approach can develop an understanding of the rules used to predict bacterial attachment to surfaces of non-toxic synthetic materials. Here we outline our view on the state of this field and the challenges and opportunities in this area for the coming years.

机译：在许多行业和临床环境中，控制微生物对材料的定殖很重要。迄今为止，控制细菌与材料表面相互作用的潜在机制仍然知之甚少，从而限制了从头开始设计和工程改造生物材料以控制细菌的附着。涉及高通量筛选的组合方法已成为识别材料以控制细菌附着的关键工具。使用这些方法评估的数百种不同材料可以借助计算模型进行。这种方法可以增进对用于预测细菌附着到无毒合成材料表面的规则的理解。在这里，我们概述了我们对该领域的现状以及未来几年该领域的挑战和机遇的看法。

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《Acta biomaterialia》 |2016年第null期|共9页
作者
Magennis E. P.; Hook A. L.; Davies M. C.; Alexander C.; Williams P.; Alexander M. R.;
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原文格式 PDF
正文语种 eng
中图分类普通生物学;
关键词
Biomaterials; Bacteria; High-throughput; Biofilm; Polymers;

机译：生物材料;细菌;高通量;生物膜;聚合物;

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专利

1. Engineering serendipity: High-throughput discovery of materials that resist bacterial attachment [J] . Magennis E. P., Hook A. L., Davies M. C., Acta biomaterialia . 2016,第Null期

机译：工程学上的意外发现：高通量发现抗细菌附着的材料
2. Engineering serendipity: High-throughput discovery of materials that resist bacterial attachment [J] . Magennis E. P., Hook A. L., Davies M. C., Acta biomaterialia . 2016,第Null期

机译：工程学上的意外发现：高通量发现抗细菌附着的材料
3. Discovery of Novel Materials with Broad Resistance to Bacterial Attachment Using Combinatorial Polymer Microarrays [J] . Andrew L. Hook, Chien-Yi Chang, Jing Yang, Advanced Materials . 2013,第18期

机译：使用组合聚合物微阵列发现对细菌附着具有广泛抵抗力的新型材料
4. Combinatorial discovery of materials that resist bacterial adhesion [C] . Andrew L. Hook, Chien-Yi Chang, Jing Yang, World biomaterials congress . 2012

机译：组合发现抗细菌粘附的材料
5. High-Throughput Materials Discovery and Its Application to Poly-Elemental Nanoparticles [D] . Liu, Mohan . 2019

机译：高通量材料发现及其在多元素纳米粒子的应用
6. Engineering serendipity: High-throughput discovery of materials that resist bacterial attachment [O] . E.P. Magennis, A.L. Hook, M.C. Davies, -1

机译：工程学上的意外发现：高通量发现抗细菌附着的材料
7. Engineering serendipity: high-throughput discovery of materials that resist bacterial attachment [O] . Magennis E.P., Hook A.L., Davies M.C., 2016

机译：工程上的意外发现：高通量发现抗细菌附着的材料

Engineering serendipity: High-throughput discovery of materials that resist bacterial attachment

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