01041nam 2200313Ia 450 99638533360331620221108035642.0(CKB)4940000000075476(EEBO)2240945236(OCoLC)12185502(EXLCZ)99494000000007547619850621d1659 uy |engurbn||||a|bb|The shepheards paradise[electronic resource] a comedy : privately acted before the late King Charls by the Queen's Majesty, and ladies of honour /written by W. Mountague EsqLondon Printed for John Starkey ...1659[6], 175 pPreface signed: T.D. (probably Thomas Dring, the publisher)Reproduction of original in Huntington Library.eebo-0113Montagu Walter1603?-1677.1001837EAAEAAm/cWaOLNBOOK996385333603316The shepheard's paradise2383061UNISA05109nam 22005894a 450 991083007140332120230617032030.01-280-27051-997866102705140-470-85651-30-470-85652-1(CKB)111056485598012(EBL)148940(OCoLC)807994952(SSID)ssj0000218586(PQKBManifestationID)11208259(PQKBTitleCode)TC0000218586(PQKBWorkID)10220433(PQKB)11496628(MiAaPQ)EBC148940(EXLCZ)9911105648559801220020813d2003 uy 0engur|n|---|||||txtccrPatch clamping[electronic resource] an introductory guide to patch clamp electrophysiology /Areles MollemanNew York J. Wileyc20031 online resource (187 p.)Description based upon print version of record.0-471-48685-X Includes bibliographical references and index.Patch Clamping; Contents; Preface; 1 Introduction; 1.1 Patch Clamping and its Context; 2 Basic Theoretical Principles; 2.1 Introduction to Membrane Biology; 2.1.1 The plasma membrane and its ionic environment; 2.1.2 Electrochemical gradients and the Nernst equation; 2.1.3 Maintenance of ion gradients and the membrane potential; 2.1.4 Ion channels; 2.2 Electrical Properties of the Cell Membrane; 2.2.1 Driving force and membrane resistance; 2.2.2 Membrane capacitance; 2.2.3 Consequences of membrane capacitance; 2.2.4 An electronic model of the plasma membrane2.3 Recording Modes and their Equivalent Circuits2.3.1 The basics of equivalent circuits; 2.3.2 Intracellular recording; 2.3.3 Voltage clamp and current clamp; 2.3.4 Introduction to patch clamp configurations; 2.3.5 The equivalent circuit for the cell-attached patch configuration; 2.3.6 The equivalent circuit for the whole-cell configuration; 2.3.7 The equivalent circuit for the excised patch configurations; 3 Requirements; 3.1 The Platform; 3.1.1 Stability: vibrations and drift; 3.1.2 Where in the building should the set-up be placed?; 3.1.3 Anti-vibration tables; 3.2 Mechanics and Optics3.2.1 The microscope3.2.2 Micromanipulators; 3.2.3 Pipette pressure; 3.2.4 Baths and superfusion systems; 3.3 Electrodes and Micropipettes; 3.3.1 Solid-liquid junction potentials and polarisation; 3.3.2 The bath electrode; 3.3.3 Micropipettes; 3.3.4 Liquid junction potentials; 3.4 Electronics; 3.4.1 External noise and Faraday cages; 3.4.2 Patch clamp amplifiers; 3.4.3 Noise prevention and signal conditioning; 3.4.4 Data acquisition and digitisation; 3.4.5 Computers and software; 4 The Practice of Patch Clamping; 4.1 Preparing the Experiment and Making a Seal; 4.1.1 Setting up4.1.2 Bringing the pipette near the preparation4.1.3 Making the seal; 4.2 Whole-cell Modes; 4.2.1 Conventional whole-cell recording; 4.2.2 Perforated patch recording; 4.3 Single-channel Modes; 4.3.1 General notes; 4.3.2 Cell-attached patch; 4.3.3 Excised patches; 5 Whole-cell Protocols and Data Analysis; 5.1 Standard Cellular Parameters; 5.2 Voltage-activated Currents; 5.2.1 Introduction to pulse protocols; 5.2.2 Signal conditioning and positive/negative subtraction; 5.2.3 Space clamp artefacts; 5.2.4 Isolation of a homogeneous population of channels5.2.5 Current-voltage relationships and reversal potential5.2.6 Determination of relative permeabilities; 5.2.7 Activation and inactivation studies; 5.3 Non-voltage-activated Currents; 5.3.1 Introduction to continuous recording; 5.3.2 Determination of reversal potential using voltage ramps; 6 Single-channel Protocols and Data Analysis; 6.1 General Single-channel Practice and Analysis; 6.1.1 Practical notes; 6.1.2 Amplitude analysis; 6.1.3 Event detection; 6.1.4 Dwell time analysis; 6.2 Continuous Recording of Single Channels; 6.2.1 Data acquisition; 6.2.2 Spontaneous activity6.2.3 Receptor-induced activityPatch clamping is a widely applied electrophysiological technique for the study of ion channels; membrane proteins that regulate the flow of ions across cellular membranes and therefore influence the physiology of all cells. Patch Clamping aims to cover the basic principles and practical applications of this important technique. Starting with a review of the history of patch clamping, the text then goes on to cover the basic principles, platforms, equipment and environmental control, and will also include coverage of preparation types, recording modes and analysis of results. <Patch-clamp techniques (Electrophysiology)Patch-clamp techniques (Electrophysiology)571.64572/.437Molleman Areles471690MiAaPQMiAaPQMiAaPQBOOK9910830071403321Patch clamping229524UNINA