Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications
Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams
Molecular Diversity Preservation International (MDPI)
Published 2018
Molecular Diversity Preservation International (MDPI)
Published 2018
| Publication Date: |
2018-07-27
|
|---|---|
| Publisher: |
Molecular Diversity Preservation International (MDPI)
|
| Electronic ISSN: |
2073-4425
|
| Topics: |
Biology
|
| Published by: |
| _version_ | 1836399015318519808 |
|---|---|
| autor | Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams |
| beschreibung | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes doi: 10.3390/genes9080375 Authors: Alexander C. Carpenter Ian T. Paulsen Thomas C. Williams Biosensors are enabling major advances in the field of analytics that are both facilitating and being facilitated by advances in synthetic biology. The ability of biosensors to rapidly and specifically detect a wide range of molecules makes them highly relevant to a range of industrial, medical, ecological, and scientific applications. Approaches to biosensor design are as diverse as their applications, with major biosensor classes including nucleic acids, proteins, and transcription factors. Each of these biosensor types has advantages and limitations based on the intended application, and the parameters that are required for optimal performance. Specifically, the choice of biosensor design must consider factors such as the ligand specificity, sensitivity, dynamic range, functional range, mode of output, time of activation, ease of use, and ease of engineering. This review discusses the rationale for designing the major classes of biosensor in the context of their limitations and assesses their suitability to different areas of biotechnological application. |
| citation_standardnr | 6309953 |
| datenlieferant | ipn_articles |
| feed_id | 128619 |
| feed_publisher | Molecular Diversity Preservation International (MDPI) |
| feed_publisher_url | http://www.mdpi.org/ |
| insertion_date | 2018-07-27 |
| journaleissn | 2073-4425 |
| publikationsjahr_anzeige | 2018 |
| publikationsjahr_facette | 2018 |
| publikationsjahr_intervall | 7984:2015-2019 |
| publikationsjahr_sort | 2018 |
| publisher | Molecular Diversity Preservation International (MDPI) |
| quelle | Genes |
| relation | http://www.mdpi.com/2073-4425/9/8/375 |
| search_space | articles |
| shingle_author_1 | Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams |
| shingle_author_2 | Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams |
| shingle_author_3 | Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams |
| shingle_author_4 | Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams |
| shingle_catch_all_1 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes doi: 10.3390/genes9080375 Authors: Alexander C. Carpenter Ian T. Paulsen Thomas C. Williams Biosensors are enabling major advances in the field of analytics that are both facilitating and being facilitated by advances in synthetic biology. The ability of biosensors to rapidly and specifically detect a wide range of molecules makes them highly relevant to a range of industrial, medical, ecological, and scientific applications. Approaches to biosensor design are as diverse as their applications, with major biosensor classes including nucleic acids, proteins, and transcription factors. Each of these biosensor types has advantages and limitations based on the intended application, and the parameters that are required for optimal performance. Specifically, the choice of biosensor design must consider factors such as the ligand specificity, sensitivity, dynamic range, functional range, mode of output, time of activation, ease of use, and ease of engineering. This review discusses the rationale for designing the major classes of biosensor in the context of their limitations and assesses their suitability to different areas of biotechnological application. Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams Molecular Diversity Preservation International (MDPI) 2073-4425 20734425 |
| shingle_catch_all_2 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes doi: 10.3390/genes9080375 Authors: Alexander C. Carpenter Ian T. Paulsen Thomas C. Williams Biosensors are enabling major advances in the field of analytics that are both facilitating and being facilitated by advances in synthetic biology. The ability of biosensors to rapidly and specifically detect a wide range of molecules makes them highly relevant to a range of industrial, medical, ecological, and scientific applications. Approaches to biosensor design are as diverse as their applications, with major biosensor classes including nucleic acids, proteins, and transcription factors. Each of these biosensor types has advantages and limitations based on the intended application, and the parameters that are required for optimal performance. Specifically, the choice of biosensor design must consider factors such as the ligand specificity, sensitivity, dynamic range, functional range, mode of output, time of activation, ease of use, and ease of engineering. This review discusses the rationale for designing the major classes of biosensor in the context of their limitations and assesses their suitability to different areas of biotechnological application. Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams Molecular Diversity Preservation International (MDPI) 2073-4425 20734425 |
| shingle_catch_all_3 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes doi: 10.3390/genes9080375 Authors: Alexander C. Carpenter Ian T. Paulsen Thomas C. Williams Biosensors are enabling major advances in the field of analytics that are both facilitating and being facilitated by advances in synthetic biology. The ability of biosensors to rapidly and specifically detect a wide range of molecules makes them highly relevant to a range of industrial, medical, ecological, and scientific applications. Approaches to biosensor design are as diverse as their applications, with major biosensor classes including nucleic acids, proteins, and transcription factors. Each of these biosensor types has advantages and limitations based on the intended application, and the parameters that are required for optimal performance. Specifically, the choice of biosensor design must consider factors such as the ligand specificity, sensitivity, dynamic range, functional range, mode of output, time of activation, ease of use, and ease of engineering. This review discusses the rationale for designing the major classes of biosensor in the context of their limitations and assesses their suitability to different areas of biotechnological application. Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams Molecular Diversity Preservation International (MDPI) 2073-4425 20734425 |
| shingle_catch_all_4 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications Genes doi: 10.3390/genes9080375 Authors: Alexander C. Carpenter Ian T. Paulsen Thomas C. Williams Biosensors are enabling major advances in the field of analytics that are both facilitating and being facilitated by advances in synthetic biology. The ability of biosensors to rapidly and specifically detect a wide range of molecules makes them highly relevant to a range of industrial, medical, ecological, and scientific applications. Approaches to biosensor design are as diverse as their applications, with major biosensor classes including nucleic acids, proteins, and transcription factors. Each of these biosensor types has advantages and limitations based on the intended application, and the parameters that are required for optimal performance. Specifically, the choice of biosensor design must consider factors such as the ligand specificity, sensitivity, dynamic range, functional range, mode of output, time of activation, ease of use, and ease of engineering. This review discusses the rationale for designing the major classes of biosensor in the context of their limitations and assesses their suitability to different areas of biotechnological application. Alexander C. Carpenter; Ian T. Paulsen; Thomas C. Williams Molecular Diversity Preservation International (MDPI) 2073-4425 20734425 |
| shingle_title_1 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications |
| shingle_title_2 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications |
| shingle_title_3 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications |
| shingle_title_4 | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications |
| timestamp | 2025-06-30T23:36:14.853Z |
| titel | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications |
| titel_suche | Genes, Vol. 9, Pages 375: Blueprints for Biosensors: Design, Limitations, and Applications |
| topic | W |
| uid | ipn_articles_6309953 |