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200 10$aMicrowave ECR ion thruster development activities at NASA Glenn Research Center /$fJohn E. Foster and Michael J. Patterson
210  1$aCleveland, Ohio :$cNational Aeronautics and Space Administration, Glenn Research Center,$dOctober 2002.
215   $a1 online resource (13 pages) $cillustrations
225 1 $aNASA/TM ;$v2002-211877
300   $a"October 2002."
300   $a"Prepared for the 38th Joint Propulsion Conference and Exhibit cosponsored by the AIAA, ASME, SAE, and ASEE, Indianapolis, Indiana, July 7-10, 2002."
300   $a"Performing organization: National Aeronautics and Space Administration, John H. Glenn Research Center at Lewis Field"--Report documentation page.
300   $a"AIAA-2002-3837."
320   $aIncludes bibliographical references (page 6).
517 3 $aMicrowave electron cyclotron resonance ion thruster development activities at NASA Glenn Research Center
606   $aHollow cathodes$2nasat
606   $aSpacecraft propulsion$2nasat
606   $aElectron cyclotron resonance$2nasat
606   $aResearch and development$2nasat
606   $aSpace missions$2nasat
606   $aMicrowaves$2nasat
606   $aIon exchanging$2nasat
615  7$aHollow cathodes.
615  7$aSpacecraft propulsion.
615  7$aElectron cyclotron resonance.
615  7$aResearch and development.
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615  7$aMicrowaves.
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700   $aFoster$b John E.$01389886
702   $aPatterson$b Michael J.$f1959-
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200 10$aAntimicrobial peptides /$fDavid A. Phoenix, Sarah R. Dennison, and Frederick Harris
210   $aWeinheim $cWiley-VCH$dc2013
215   $a1 online resource (254 p.)
300   $aDescription based upon print version of record.
311 08$a9783527332632 
311 08$a3527332634 
320   $aIncludes bibliographical references and index.
327   $aCover; Related Titles; Title page; Copyright page; Contents; Preface; References; List of Abbreviations; 1: Antimicrobial Peptides: Their History, Evolution, and Functional Promiscuity; Summary; 1.1 Introduction: The History of Antimicrobial Peptides; 1.2 AMPs: Evolutionarily Ancient Molecules; 1.3 AMPs: Multifunctional Molecules; 1.3.1 Defensins as Effectors of Immunity; 1.3.2 Defensins and Wound Healing; 1.3.3 Defensins and Canine Coat Color; 1.4 Discussion; References; 2: Cationic Antimicrobial Peptides; Summary; 2.1 Introduction; 2.2 CAMPs and Their Antimicrobial Action
327   $a2.3 CAMPs That Adopt an ?-Helical Structure2.4 CAMPs That Adopt a ?-Sheet Structure; 2.5 CAMPs That Adopt Extended Structures Rich in Specific Residues; 2.6 Discussion; References; 3: Anionic Antimicrobial Peptides; Summary; 3.1 Introduction; 3.2 AAMPs in the Respiratory Tract; 3.3 AAMPs in the Brain; 3.4 AAMPs in the Epidermis; 3.5 AAMPs in the Epididymis; 3.6 AAMPs in Blood Components; 3.7 AAMPs in the Gastrointestinal Tract and Food Proteins; 3.8 AAMPs and Their Structure-Function Relationships; 3.9 Discussion; References
327   $a4: Graphical Techniques to Visualize the Amphiphilic Structures of Antimicrobial PeptidesSummary; 4.1 Introduction; 4.2 Amphiphilic Structures Adopted by AMPs; 4.3 Qualitative Methods for Identifying Amphiphilic Structure; 4.4 Quantitative Techniques for Analyzing Amphiphilic Structure; 4.4.1 Techniques Based on Hydropathy Plot Analysis; 4.4.2 Techniques Based on Fourier Transforms; 4.4.3 Amphipathic Index; 4.4.4 Hydrophobic Moment Analysis; 4.4.5 Classification of Amphiphilic ?-Helices Using the Approach of Segrest; 4.4.6 Amphiphilicity Profiling Analysis of Tilted ?-Helices
327   $a4.4.7 Extended Hydrophobic Moment Plot Analysis of Tilted ?-Helices4.4.8 Amphiphilicity Quantified Using the Approach of Keller; 4.4.9 Amphiphilicity Quantified Using the Approach of Brasseur; 4.5 Discussion; References; 5: Models for the Membrane Interactions of Antimicrobial Peptides; Summary; 5.1 Introduction; 5.2 CM-Associated Factors That Affect the Antimicrobial Action of ?-CAMPs; 5.3 Mechanisms Used by CAMPs for Microbial Membrane Interaction; 5.4 Established Models for the Membrane Interactions of ?-AMPs; 5.4.1 Barrel-Stave and Toroidal Pore Models
327   $a5.4.2 Carpet Mechanism and the Shai-Huang-Matsazuki Model5.5 Recent Novel Models for the Membrane Interactions of ?-AMPs; 5.6 Tilted Peptide Mechanism; 5.7 Amyloidogenic Mechanisms; 5.8 Discussion; References; 6: Selectivity and Toxicity of Oncolytic Antimicrobial Peptides; Summary; 6.1 Introduction; 6.2 Peptide-Based Factors That Contribute to the Anticancer Action of Anticancer Peptides; 6.2.1 Sequence Length; 6.2.2 Net Positive Charge; 6.2.3 Hydrophobicity; 6.2.4 Amphiphilicity; 6.3 Membrane-Based Factors That Contribute to the Anticancer Action of ACPs; 6.3.1 Membrane Receptors
327   $a6.3.2 Cholesterol
330   $aIn this didactically-written text, the small team of expert authors presents the field in a comprehensive and accessible manner that is well suited for students and junior researchers.The result is a highly readable and systematically structured introduction to antimicrobial peptides, their structure, biological function and mode of action. The authors point the way towards a rational design of this potentially highly effective new class of clinical antibiotics on the brink of industrial application by discussing their design principles, target membranes and structure-activity relationship
606   $aPeptide antibiotics
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