03251nam 2200721 a 450 991081155670332120230801232622.097811199621061119962102978129918939312991893939781119962090111996209997811199621201119962129(CKB)3460000000080859(EBL)819205(OCoLC)815648293(SSID)ssj0000622287(PQKBManifestationID)11385800(PQKBTitleCode)TC0000622287(PQKBWorkID)10639543(PQKB)11062534(MiAaPQ)EBC819205(Au-PeEL)EBL819205(CaPaEBR)ebr10575568(CaONFJC)MIL450189(Perlego)1011325(EXLCZ)99346000000008085920110613d2012 uy 0engurcn|||||||||txtccrHow to present at meetings /edited by George M. Hall, Neville Robinson3rd ed.Chichester, West Sussex [England] John Wiley & Sons20121 online resource (108 p.)HOW - How ToDescription based upon print version of record.9780470654583 0470654589 Includes bibliographical references and index.Principles of communication / Angela Hall and Peter McCrorie -- Preparation of the talk / Mal Morgan and George M. Hall -- The three talks / Mal Morgan and George M. Hall -- Visual aids / George M. Hall -- Poster displays / Philip M. Sedgwick -- Data projection software: the hard facts / William Harrop-Griffiths -- How to appear on stage / Alan Maryon-Davis -- How to sell a message / Martin Godfrey -- How to present a talk / Charlotte Green -- How to deal with questions / Sir Alexander Macara -- How not to give a presentation / Richard Smith -- How to chair a session / Roger Horton.Does the thought of presenting a paper make you go cold? There are so many things to consider: getting your message across clearly, making the PowerPoint easy to read, keeping to the right length and keeping the audience riveted - enough to induce nerves even without the thought of standing up in front of a crowd and delivering your talk fluently. How to Present at Meetings, 3rd Edition, gives you practical advice on all these aspects, and more. Written by high-profile public speakers in the health sciences, it includes chapters on the 10-, 20- and 45-minute presentation,HOW - How ToCommunication in medicineLectures and lecturingCommunication of technical informationCommunication in medicine.Lectures and lecturing.Communication of technical information.610.69/6Hall George M(George Martin)287416Robinson Neville855901MiAaPQMiAaPQMiAaPQBOOK9910811556703321How to present at meetings3977333UNINA04261nam 2200721 a 450 991095353080332120250609111454.01-280-20496-697866102049600-306-46934-010.1007/0-306-46934-0(CKB)111056486602290(EBL)3035688(SSID)ssj0000127552(PQKBManifestationID)11143131(PQKBTitleCode)TC0000127552(PQKBWorkID)10054333(PQKB)10098124(DE-He213)978-0-306-46934-3(Au-PeEL)EBL3035688(CaPaEBR)ebr10053003(CaONFJC)MIL20496(OCoLC)923696549(PPN)237929422(MiAaPQ)EBC3035688(MiAaPQ)EBC196723(EXLCZ)9911105648660229019970306d1997 uy 0engur|n|---|||||txtccrComputational approaches to biochemical reactivity /edited by Gabor Naray-Szabo and Arieh Warshel1st ed. 2002.Dordrecht ;Boston Kluwer Academicc19971 online resource (392 p.)Understanding chemical reactivity ;v. 19Description based upon print version of record.1-4020-0415-X 0-7923-4512-6 Includes bibliographical references and index.Quantum Mechanical Models for Reactions in Solution -- Free Energy Perturbation Calculations within Quantum Mechanical Methodologies -- Hybrid Potentials for Molecular Systems in the Condensed Phase -- Molecular Mechanics and Dynamics Simulations of Enzymes -- Electrostatic Interactions in Proteins -- Electrostatic Basis of Enzyme Catalysis -- On the Mechanisms of Proteinases -- Modelling of Proton Transfer Reactions in Enzymes -- Protein-Ligand Interactions.A quantitative description of the action of enzymes and other biological systems is both a challenge and a fundamental requirement for further progress in our und- standing of biochemical processes. This can help in practical design of new drugs and in the development of artificial enzymes as well as in fundamental understanding of the factors that control the activity of biological systems. Structural and biochemical st- ies have yielded major insights about the action of biological molecules and the mechanism of enzymatic reactions. However it is not entirely clear how to use this - portant information in a consistent and quantitative analysis of the factors that are - sponsible for rate acceleration in enzyme active sites. The problem is associated with the fact that reaction rates are determined by energetics (i. e. activation energies) and the available experimental methods by themselves cannot provide a correlation - tween structure and energy. Even mutations of specific active site residues, which are extremely useful, cannot tell us about the totality of the interaction between the active site and the substrate. In fact, short of inventing experiments that allow one to measure the forces in enzyme active sites it is hard to see how can one use a direct experimental approach to unambiguously correlate the structure and function of enzymes. In fact, in view of the complexity of biological systems it seems that only computers can handle the task of providing a quantitative structure-function correlation.Understanding chemical reactivity ;v. 19.BiochemistryMathematical modelsEnzyme kineticsQuantum biochemistryLigand binding (Biochemistry)Mathematical modelsBiochemistryMathematical models.Enzyme kinetics.Quantum biochemistry.Ligand binding (Biochemistry)Mathematical models.572/.44/015118Náray-Szabó Gábor1823780Warshel Arieh1823781MiAaPQMiAaPQMiAaPQBOOK9910953530803321Computational approaches to biochemical reactivity4390725UNINA