Gigaseal Formation in Patch Clamping [electronic resource] : With Applications of Nanotechnology / by Majid Malboubi, Kyle Jiang.

By: Malboubi, Majid [author.]Contributor(s): Jiang, Kyle [author.] | SpringerLink (Online service)Material type: TextTextLanguage: English Series: SpringerBriefs in Applied Sciences and Technology: Publisher: Berlin, Heidelberg : Springer Berlin Heidelberg : Imprint: Springer, 2014Description: XI, 94 p. 81 illus., 65 illus. in color. online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9783642391286Subject(s): Engineering | Biomedical engineering | Engineering | Nanotechnology and Microengineering | Biomedical EngineeringAdditional physical formats: Printed edition:: No titleDDC classification: 620.5 LOC classification: T174.7Online resources: Click here to access online
Contents:
Chapter 1 Introduction -- Chapter 2 Development of patch clamping -- Chapter 3 Gigaseal formation -- Chapter 4 Effect of roughness on gigaseal formation -- Chapter 5 Effect of hydrophilicIty on gigaseal formation -- Chapter 6 Effect of tip size on gigaseal formation -- Chapter 7 Study of glass micropipettes from tip formation to characterization -- References.
In: Springer eBooksSummary: This book presents an investigation of gigaseal formation using micro/nanotechnology. The aims of the book are twofold. First, it explains the mechanisms of gigaseal formation using the latest discoveries. Second, it provides practical techniques for frequent formation of high resistance seals. The formation of a high-resistance electrical seal, also known as a gigaseal, between a cell membrane and a glass micropipette tip is essential in patch-clamp experiments. Even though four decades have passed since the introduction of the patch-clamping technique by Neher and Sakmann, gigaseal formation remains an obstacle in developing the high-throughput ion channel screening systems required by the pharmaceutical industry. Here the authors share their latest methods for achieving gigaseal formation and describe techniques that are highly desirable at both research and industrial levels. Nanotechnology has been found to be a powerful tool for studying and modifying glass micropipettes and in tackling the problem of gigaseal formation.
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Chapter 1 Introduction -- Chapter 2 Development of patch clamping -- Chapter 3 Gigaseal formation -- Chapter 4 Effect of roughness on gigaseal formation -- Chapter 5 Effect of hydrophilicIty on gigaseal formation -- Chapter 6 Effect of tip size on gigaseal formation -- Chapter 7 Study of glass micropipettes from tip formation to characterization -- References.

This book presents an investigation of gigaseal formation using micro/nanotechnology. The aims of the book are twofold. First, it explains the mechanisms of gigaseal formation using the latest discoveries. Second, it provides practical techniques for frequent formation of high resistance seals. The formation of a high-resistance electrical seal, also known as a gigaseal, between a cell membrane and a glass micropipette tip is essential in patch-clamp experiments. Even though four decades have passed since the introduction of the patch-clamping technique by Neher and Sakmann, gigaseal formation remains an obstacle in developing the high-throughput ion channel screening systems required by the pharmaceutical industry. Here the authors share their latest methods for achieving gigaseal formation and describe techniques that are highly desirable at both research and industrial levels. Nanotechnology has been found to be a powerful tool for studying and modifying glass micropipettes and in tackling the problem of gigaseal formation.

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