Current understanding of multi-species biofilms 被引量：6

Current understanding of multi-species biofilms

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摘要 Direct observation of a wide range of natural microorganisms has revealed the fact that the majority of microbes persist as surface-attached communities surrounded by matrix materials, called biofilms. Biofilms can be formed by a single bacterial strain. However, most natural biofilms are actually formed by multiple bacterial species. Conventional methods for bacterial cleaning, such as applications of antibiotics and/or disinfectants are often ineffective for biofilm populations due to their special physiology and physical matrix barrier. It has been estimated that billions of dollars are spent every year worldwide to deal with damage to equipment, contamina- tions of products, energy losses, and infections in human beings resulted from microbial biofilms. Microorganisms compete, cooperate, and communicate with each other in multi-species biofilms. Understanding the mechanisms of multi-species hiofilm formation will facilitate the development of methods for combating bacterial hiofilms in clinical, environmental, industrial, and agricultural areas. The most recent advances in the understanding of multi-species biofilms are summarized and discussed in the review. Direct observation of a wide range of natural microorganisms has revealed the fact that the majority of microbes persist as surface-attached communities surrounded by matrix materials, called biofilms. Biofilms can be formed by a single bacterial strain. However, most natural biofilms are actually formed by multiple bacterial species. Conventional methods for bacterial cleaning, such as applications of antibiotics and/or disinfectants are often ineffective for biofilm populations due to their special physiology and physical matrix barrier. It has been estimated that billions of dollars are spent every year worldwide to deal with damage to equipment, contamina- tions of products, energy losses, and infections in human beings resulted from microbial biofilms. Microorganisms compete, cooperate, and communicate with each other in multi-species biofilms. Understanding the mechanisms of multi-species hiofilm formation will facilitate the development of methods for combating bacterial hiofilms in clinical, environmental, industrial, and agricultural areas. The most recent advances in the understanding of multi-species biofilms are summarized and discussed in the review.

作者 Liang Yang Yang Liu Hong Wu Niels Hoiby Soren Molin Zhi-jun Song

机构地区 Department of Systems Biology Department of Clinical Microbiology

出处《International Journal of Oral Science》 SCIE CAS CSCD 2011年第2期74-81,共8页 国际口腔科学杂志（英文版）

关键词 biofilms extracellular polymeric substances structure development INTERACTIONS biofilms extracellular polymeric substances structure development interactions

分类号 TS941.6 [轻工技术与工程—服装设计与工程] Q73 [生物学—分子生物学]

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International Journal of Oral Science

2011年第2期

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Current understanding of multi-species biofilms 被引量：6

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