Search | Unterhaltung

protein gefunden in Unterhaltung

Zeige 10 von 1 110 Produkte

nur Aktionen :

Sortierung :

Ansicht :

✖

CHF 168.00

Retinal Gene Therapy

Part I: Retinal Gene Therapy Vector Production and Biological Assays In Vitro 1. Small Scale Production of Recombinant Adeno-Associated Viral Vectors for Gene Delivery to the Nervous System Joost Verhaagen, Barbara Hobo, Erich M.E. Ehlert, Ruben Eggers, Joanna A. Korecka, Stefan A. Hoyng, Callan L. Attwell, Alan R. Harvey, and Matthew R.J. Mason 2. Small and Micro...

4909085 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvMmMvNGYvOTYvNjY0NjM5NTcwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvMmMvNGYvOTYvNjY0NjM5NTcwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2M0LXN0YXRpYy5kb2RheC5jb20vdjIvMTgwLTE4MC0xMjE0Mjg0NzdfanhMUnFqLXBuZw==","post_title":"Retinal Gene Therapy","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9781493975211&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fmedizin-pharmazie%2F378094%2Fretinal-gene-therapy-methods-and-protocols%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"Part I: Retinal Gene Therapy Vector Production and Biological Assays In Vitro 1. Small Scale Production of Recombinant Adeno-Associated Viral Vectors for Gene Delivery to the Nervous System Joost Verhaagen, Barbara Hobo, Erich M.E. Ehlert, Ruben Eggers, Joanna A. Korecka, Stefan A. Hoyng, Callan L. Attwell, Alan R. Harvey, and Matthew R.J. Mason 2. Small and Micro-Scale Recombinant Adeno-Associated Virus Production and Purification for Ocular Gene Therapy Applications Christopher A. Reid and Daniel M. Lipinski 3. Design and Development of AAV-Based Gene Supplementation Therapies for Achromatopsia and Retinitis Pigmentosa Christian Sch\u00f6n, Elvir Becirovic, Martin Biel, and Stylianos Michalakis 4. Development of Multigenic Lentiviral Vectors for Cell-Specific Expression of Antiangiogenic miRNAs and Protein Factors Anne Louise Askou and Thomas J. Corydon 5. Design and In Vitro Use of Antisense Oligonucleotides to Correct Pre-mRNA Splicing Defects in Inherited Retinal Dystrophies Alejandro Garanto and Rob W.J. Collin 6. Three-Dimensional Co-Culture Bioassay for Screening of Retinal Gene Delivery Systems Ding Wen Chen, Kathleen Pauloff, and Marianna Foldvari 7. Retinal Gene Therapy for Choroideremia: In Vitro Testing for Gene Augmentation Using an Adeno-Associated Viral (AAV) Vector Maria I. Patr\u00edcio and Robert E. MacLaren Part II: Assays for Gene Augmentation and Editing In Vivo on Rodent and Macaque Retina 8. In Vivo Electroporation of Developing Mouse Retina Jimmy de Melo and Seth Blackshaw 9. Methods for In Vivo CRISPR\/Cas Editing of the Adult Murine Retina Sandy S. Hung, Fan Li, Jiang-Hui Wang, Anna E. King, Bang V. Bui, Guei-Sheung Liu, and Alex W. Hewitt 10. AAV Gene Augmentation Therapy for CRB1-Associated Retinitis Pigmentosa C. Henrique Alves and Jan Wijnholds 11. Dual AAV Vectors for Stargardt Disease Ivana Trapani 12. Optogenetic Retinal Gene Therapy with the Light Gated GPCR Vertebrate Rhodopsin Benjamin M. Gaub, Michael H. Berry, Meike Visel, Amy Holt, Ehud Y. Isacoff, and John G. Flannery 13. CRISPR Repair Reveals Causative Mutation in a Preclinical Model of Retinitis Pigmentosa: A Brief Methodology Wen-Hsuan Wu, Yi-Ting Tsai, Sally Justus, Galaxy Y Cho, Jesse D Sengillo, Yu Xu, Thiago Cabral, Chyuan-Sheng Lin, Alexander G. Bassuk, Vinit B. Mahajan, and Stephen H. Tsang 14. In-Depth Functional Analysis of Rodents by Full-Field Electroretinography Vithiyanjali Sothilingam, Regine M\u00fchlfriedel, Naoyuki Tanimoto, and Mathias W. Seeliger 15. Advanced Ocular Injection Techniques for Therapy Approaches Regine M\u00fchlfriedel, Marina Garcia Garrido, Christine Wallrapp, and Mathias W. Seeliger 16. Neutralizing Antibodies Against Adeno-Associated Virus (AAV): Measurement and Influence on Retinal Gene Delivery M\u00e9lissa Desrosiers and Deniz Dalkara 17. Screening for Neutralizing Antibodies against Natural and Engineered AAV Capsids in Non-Human Primate Retinas Timothy P. Day, Leah C. Byrne, John G. Flannery, and David V. Schaffer 18. Subretinal and Intravitreal Retinal Injections in Monkeys Daniyar Dauletbekov, K. Ulrich Bartz-Schmidt, and M. Dominik Fischer Part III: Clinical Protocols and Retinal Gene Therapy Vector Testing on Human Retina 19. Production of iPS-derived Human Retinal Organoids for Use in Transgene Expression Assays Peter M. Quinn, Thilo M. Buck, Charlotte Ohonin, Harald Mikkers, and Jan Wijnholds 20. AAV Serotype Testing on Cultured Human Donor Retinal Explants Thilo M. Buck, Lucie P. Pellissier, Rogier M. Vos, Elon H.C. van Dijk, Camiel J.F. Boon, and Jan Wijnholds 21. Human Retinal Explant Culture for Ex-Vivo Validation of AAV Gene Therapy Harry O. Orlans, Thomas L. Edwards, Samantha R. De Silva, Maria I. Patr\u00edcio, and Robert E. MacLaren 22. Visual Acuity Testing Before and After Intravitreal Injection of rAAV2- ND4 in Patients Bin Li and Chenmian Wu 23. Recording and Analysis of the Human Clinical Electroretinogram Mathieu Gauvin, Allison L. Dorfman, and Pierre Lachapelle 24. Recording and Analysis of Goldmann Kinetic Visual Fields Mays Talib, Gislin Dagnelie, and Camiel J.F. Boon 25. Measuring Central Retinal Sensitivity Using Microperimetry Mays Talib, Jasleen K. Jolly, and Camiel J.F. Boon 26. Inspection of the Human Retina by Optical Coherence Tomography Thomas Theelen and Michel M. Teussink 27. Vector Shedding and Immunogenicity Sampling for Retinal Gene Therapy Alun R. Barnard, Anna N. Rudenko, and Robert E. MacLaren","merchants_number":2,"ean":9781493975211,"category_id":103,"size":null,"min_price":168,"low_price_merchant_id":70255345,"ID":4909085,"merchants":["euniverse","dodax"],"brand":"undefined","slug":"retinal-gene-therapy","url":"\/unterhaltung\/produkt\/retinal-gene-therapy\/","low_price_merchant_name":"eUniverse"}

Biomarker lebensmittel- und umweltrelevanter Xenobiotika

CHF 42.90

Biomarker lebensmittel- und umweltrelevanter Xenobiotika

Polyzyklische aromatische Kohlenwasserstoffe (PAK) repräsentieren eine Klasse von Xenobiotika, die ? neben anderen Quellen ? in unterschiedlichen Arten von Lebensmitteln auftreten. Nach der Nahrungsaufnahme werden die PAK bereits beim Passieren des Gastrointestinaltraktes durch Phase-I- und Phase-II-Enzyme metabolisiert. Die hierbei gebildeten Metaboliten unterliegen anschliessend ein...

4064055 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/","post_title":"Biomarker lebensmittel- und umweltrelevanter Xenobiotika","deeplink":"https:\/\/www.awin1.com\/pclick.php?p=31908910713&a=401125&m=13971&pref1=9783869554426","labels":[],"brand_id":1,"post_content":"Polyzyklische aromatische Kohlenwasserstoffe (PAK) repr\u00e4sentieren eine Klasse von Xenobiotika, die ? neben anderen Quellen ? in unterschiedlichen Arten von Lebensmitteln auftreten. Nach der Nahrungsaufnahme werden die PAK bereits beim Passieren des Gastrointestinaltraktes durch Phase-I- und Phase-II-Enzyme metabolisiert. Die hierbei gebildeten Metaboliten unterliegen anschliessend einem Transport durch die in den Epithelzellen entlang des Verdauungstraktes lokalisierten Proteine der ATP-binding cassette-Familie. PAK k\u00f6nnen \u00fcber ihre jeweiligen Dihydrodiole zu den biologisch aktiven Dihydrodiolepoxiden umgesetzt werden, welche \u00fcber die F\u00e4higkeit verf\u00fcgen, genotoxische DNA-Addukte zu bilden. Es besteht jedoch die M\u00f6glichkeit der Detoxifizierung der Dihydrodiolepoxide durch Konjugationsreaktionen mit Glutathion (GSH) sowie einer nachfolgenden Exkretion der gebildeten Konjugate aus der Zelle. Mit dem Ziel der Bestimmung von GSH-Konjugaten der kanzerogenen PAK Benzo[a]pyren (B[a]P), Dibenzo[a,l]pyren (DB[a,l]P) und Benzo[c]phenanthren (B[c]Phe) wurden spezifische LC-ESI-MS\/MS-Methoden entwickelt. Medium- und Zellextraktproben von Caco-2-Zellkulturen, die mit den Dihydrodiolen oder Dihydrodiolepoxiden eines jeweiligen PAK zuvor inkubiert worden waren, unterlagen zun\u00e4chst einem Aufreinigungsschritt mittels Festphasenextraktion (SPE). F\u00fcr die Quantifizierung der GSH-Konjugate erwies sich die LC MS\/MS-Technik im Selected Reaction Monitoring (SRM)-Modus aufgrund der guten Sensitivit\u00e4t und Selektivit\u00e4t als am besten geeignet. W\u00e4hrend dieses Prozesses erfolgte eine Fragmentierungsreaktion des jeweiligen Molek\u00fcl-Ions zu seinem korrespondierenden Daughter-Ion. Zus\u00e4tzliche massenspektrometrische Scan-Modi, wie der Daughter Scan (DAU)-Modus, fanden im Rahmen von Strukturaufkl\u00e4rungen Anwendung. Die Detoxifizierung mittels GSH-Konjugation konnte im Caco-2-Zellmodell f\u00fcr die Substanzklasse der PAK anhand ihrer Vertreter B[a]P, DB[a,l]P und B[c]Phe mit der entwickelten Analytik erfolgreich untersucht werden. Hierbei lag der Fokus auf der Entgiftung der ultimal kanzerogenen Dihydrodiolepoxide (+)-anti-BPDE, (-)-anti-DBPDE sowie (-)-anti-BcPheDE. Dieser Prozess beinhaltete sowohl die Bildung der GSH-Konjugate als auch deren Transport aus der Caco-2-Zelle in das umgebende Medium, der im TranswellTM-System \u00fcberwiegend in basolateraler Richtung erfolgte und daher einer Exkretion in Richtung Blutkreislauf gleichzusetzen war. Das entwickelte analytische Verfahren erlaubte folglich die Durchf\u00fchrung von Transportexperimenten in Zellkultur, ohne dass isotopenmarkierte Substanzen eingesetzt werden mussten. Durch Vorbehandlung des Zellsystems mit spezifischen Hemmstoffen konnten die Multidrug Resistance-associated Proteins und nicht das Breast Cancer Resistance Protein als verantwortliche Transporter von GSH-Konjugaten identifiziert werden. Einfl\u00fcsse ausgew\u00e4hlter Substanzen mit chemopr\u00e4ventivem Potential, wie Oltipraz, Quercetin und Butyrat, bewirkten \u00fcberdies detoxifizierungs-f\u00f6rdernde Effekte durch Induktion der GSH-Konjugat-Transportrate. Des Weiteren gaben Inkubationen von Caco-2-Zellen mit den Mutterkohlenwasserstoffen B[a]P, DB[a,l]P und B[c]Phe Aufschluss \u00fcber die metabolische Kompetenz der Zellen und das jeweilige Gesamtmetabolitenprofil. Typische niedermolekulare aromatische Kohlenwasserstoffe mit nur einem Ringsystem sind Benzol und Toluol, die auch zu den volatile organic compounds (VOC) gez\u00e4hlt werden. Die genannten VOC k\u00f6nnen \u00fcber Lebensmittel aufgenommen werden, wobei die Produkte durch eine externe Kontamination belastet sein k\u00f6nnen. Im Falle des Benzols wird auch eine m\u00f6gliche Bildung aus dem Konservierungsstoff Benzoes\u00e4ure diskutiert. Dar\u00fcber hinaus sind ebenfalls inhalative Belastungen durch Abgase sowie speziell bei Rauchern der Zigarettenrauch als Hauptaufnahmequelle f\u00fcr Benzol anzuf\u00fchren. Nach Inhalation, dermaler oder oraler Exposition werden Benzol und Toluol im menschlichen K\u00f6rper zu ihren korrespondierenden Mercapturs\u00e4uren verstoffwechselt, die neben anderen Metaboliten mit dem Urin ausgeschieden werden. Dieser Detoxifizierungsprozess kann f\u00fcr analytische Untersuchungen im Sinne der Bestimmung von Belastungsmarkern herangezogen werden und stellt gleichzeitig eine nicht-invasive Technik dar. Dem Clean-Up der Urinproben mittels SPE wurde eine Schwefels\u00e4urebehandlung der Urine vorgeschaltet, um eine quantitative Umwandlung von pr\u00e4-Mercapturs\u00e4uren in Mercapturs\u00e4uren zu erreichen. Mit dieser entwickelten Methode liess sich folglich der Gesamtgehalt an S-Phenylmercapturs\u00e4ure (S PMA) ermitteln. Zur Bestimmung der als Biomarker fungierenden Mercapturs\u00e4uren diente die LC-MS\/MS-Technik, wobei aufgrund der hohen Empfindlichkeit ebenfalls der SRM-Modus zum Einsatz gelangte. Die im Vergleich zu Nichtrauchern in Raucher-Urinen gefundenen h\u00f6heren S-PMA-Gehalte verdeutlichen einen st\u00e4rkeren Belastungsgrad der Raucher mit Benzol. Demgegen\u00fcber liessen sich in Raucher- und Nichtraucher-Urinen vergleichbare Konzentrationen der S-Benzylmercapturs\u00e4ure nachweisen, was m\u00f6glicherweise auf eine \u00e4hnliche Belastung mit Toluol schliessen l\u00e4sst. Die S-Naphthylmercapturs\u00e4ure als Biomarker des PAKs Naphthalin konnte im Zuge der Untersuchungen nicht detektiert werden. Die entwickelte Methode wurde dar\u00fcber hinaus zu einer qualitativen Analyse weiterer Mercapturs\u00e4uren lebensmittelrelevanter Fremdstoffe herangezogen. Die zus\u00e4tzlich zum massenspektrometrischen SRM-Modus eingesetzten DAU- und Constant Neutral Loss (CNL)-Modi detektierten hierbei die charakteristischen Masse\/Ladungs-Verh\u00e4ltnisse der Mercapturs\u00e4uren von Glycidamid, Glycidol und Acrolein. Dabei zeigte sich aufgrund gruppenspezifischer Fragmente eine m\u00f6gliche Anwendbarkeit der Methode auch f\u00fcr unbekannte Mercapturs\u00e4uren. Zusammenfassend kann man feststellen, dass die in der vorliegenden Arbeit entwickelten analytischen Methoden eine selektive und sensitive Bestimmung von sowohl GSH-Konjugaten als auch Mercapturs\u00e4uren unter in-vitro- und in-vivo-Bedingungen mittels LC MS\/MS erlauben, welche als Biomarker einer Entgiftung intermedi\u00e4rer reaktiver Metaboliten von kanzerogenen Fremdstoffen grosse Aufmerksamkeit verdienen.","merchants_number":1,"ean":9783869554426,"category_id":103,"size":null,"min_price":42.89999999999999857891452847979962825775146484375,"low_price_merchant_id":70254503,"ID":4064055,"merchants":["orell-fuessli"],"brand":"undefined","slug":"biomarker-lebensmittel-und-umweltrelevanter-xenobiotika","url":"\/unterhaltung\/produkt\/biomarker-lebensmittel-und-umweltrelevanter-xenobiotika\/","low_price_merchant_name":"Orell F\u00fcssli"}

CHF 168.00

Genome Instability

1. The A-like Faker Assay for Measuring Yeast Chromosome III StabilityCarolina A. Novoa, J. Sidney Ang, and Peter C. Stirling 2. The Chromosome Transmission Fidelity Assay for Measuring Chromosome Loss in Yeast Supipi Duffy and Philip Hieter 3. Measuring Mutation Rates using the Luria-Delbrück Fluctuation AssayGregory I. Lang 4. Molecular Genetic Characterization of Mutagenesis Using ...

4679741 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvNTYvNjgvNDAvNjQ5MDk4OTcwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvNTYvNjgvNDAvNjQ5MDk4OTcwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2kud2VsdGJpbGQuZGUvcC9nZW5vbWUtaW5zdGFiaWxpdHktMjczNTQ3NDk1LmpwZw==","post_title":"Genome Instability","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9781493973057&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fmedizin-pharmazie%2F378031%2Fgenome-instability-methods-and-protocols%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"1. The A-like Faker Assay for Measuring Yeast Chromosome III StabilityCarolina A. Novoa, J. Sidney Ang, and Peter C. Stirling\u00a02. The Chromosome Transmission Fidelity Assay for Measuring Chromosome Loss in Yeast Supipi Duffy and Philip Hieter\u00a03. Measuring Mutation Rates using the Luria-Delbr\u00fcck Fluctuation AssayGregory I. Lang\u00a04. Molecular Genetic Characterization of Mutagenesis Using a Highly Sensitized Single-Stranded DNA Reporter System in Budding YeastKin Chan5. Analyzing Genome Rearrangements in Saccharomyces cerevisiaeAnjana Srivatsan, Christopher D. Putnam, and Richard D. Kolodner\u00a06. High Resolution Mapping of Modified DNA Nucleobases using Excision Repair EnzymesMonica Ransom, D. Suzi Bryan and Jay R. Hesselberth\u00a07. Integrated Microarray-based Tools for Detection of Genomic DNA Damage and Repair MechanismsPatrick van Eijk, Yumin Teng, Mark R. Bennet, Katie E. Evans, James R. Powell, Richard M. Webster, and Simon H. Reed\u00a08. Study of UV-induced DNA Repair Factor Recruitment: Kinetics and Dynamics Sertic S., Roma S., Plevani P., Lazzaro F. , and Muzi-Falconi M.\u00a09. Inserting Site-specific DNA Lesions into Whole GenomesVincent Pag\u00e8s and Robert P Fuchs\u00a010. A qPCR-based Protocol to Quantify DSB ResectionMatteo Ferrari, Shyam Twayana, Federica Marini, and Achille Pellicioli\u00a011. Alkaline Denaturing Southern Blot Analysis to Monitor Double-strand Break ProcessingChiara Vittoria Colombo, Luca Menin, and Michela Clerici\u00a012. Single Molecule Analysis of Resection TracksPablo Huertas and Andr\u00e9s Cruz-Garc\u00eda\u00a013. Mapping DNA Breaks by Next-generation SequencingLaura Baranello, Fedor Kouzine, Damian Wojtowicz, Kairong Cui, Keji Zhao,Teresa M Przytycka, Giovanni Capranico, and David Levens14. Genome-wide Profiling of DNA Double-strand Breaks by the BLESS and BLISS MethodsReza Mirzazadeh, Tomasz Kallas, Magda Bienko, and Nicola Crosetto\u00a015. DNA Replication Profiling using Deep SequencingXanita Saayman, Cristina Ramos-P\u00e9rez, and Grant W Brown\u00a016. Quantitative Bromodeoxyuridine Immunoprecipitation Analyzed by High-Throughput Sequencing (qBrdU-seq or QBU)Joanna E. Haye-Bertolozzi and Oscar M. Aparicio \u00a017. Strand-specific Analysis of DNA Synthesis and Proteins Association with DNA Replication Forks in Budding YeastChuanhe Yu, Haiyun Gan, and Zhiguo Zhang\u00a018. Analysis of Replicative Polymerase Usage by Ribonucleotide IncorporationAndrea Keszthelyi, Izumi Miyabe, Katie Ptasinska, Yasukazu Daigaku, Karel Naiman, and Antony M. Carr\u00a019. Dynamic Architecture of Eukaryotic DNA Replication Forks in vivo, Visualized by Electron Microscopy Ralph Zellweger and Massimo Lopes\u00a020. A Molecular Toolbox to Engineer Site-Specific DNA Replication PerturbationNicolai B. Larsen, Ian D. Hickson, and Hocine W. Mankouri\u00a0 21. Single Cell Gel Electrophoresis for the Detection of Genomic Ribonucleotides Barbara Kind, Christine Wolf, Kerstin Engel, Alexander Rapp,M. Cristina Cardoso, and \u00a0Min Ae Lee-Kirsch\u00a022. Measuring the Levels of Ribonucleotides Embedded in Genomic DNAMeroni A., Nava G.M., Sertic S., Plevani P., Muzi-Falconi M.and Lazzaro F.\u00a023. Mapping Ribonucleotides Incorporated into DNA by Hydrolytic End-SequencingClinton D. Orebaugh, Scott A. Lujan, Adam B. Burkholder, Anders R Clausen, and Thomas A. Kunkel\u00a024. Detection of DNA-RNA Hybrids in vivoMar\u00eda Garc\u00eda-Rubio, Sonia I. Barroso, and Andr\u00e9s Aguilera\u00a025. Analysis of de novo Telomere Addition by Southern BlotDiego Bonetti and Maria Pia Longhese\u00a026. Assays to Study Repair of Inducible DNA Double Strand Breaks at TelomeresRoxanne Oshidari and Karim Mekhail\u00a027. Telomerase RNA Imaging in Budding Yeast and Human Cells by Fluorescent in situ HybridizationDavid Gu\u00e9rit, Maxime Lalonde, and Pascal Chartrand\u00a028. Methods to Study Repeat Fragility and Instability in Saccharomyces cerevisiaeErica J. Polleys and Catherine H. Freudenreich29. Quantitative Analysis of the Rates for Repeat-mediated Genome Instability in a Yeast Experimental SystemElina A. Radchenko, Ryan J. McGinty, Anna Y. Aksenova, Alexander J. Neil, and Sergei M. Mirkin1\u00a030. Measuring Dynamic Behaviour of Trinucleotide Repeat Tracts in vivo in Saccharomyces cerevisiaeGregory M. Williams and Jennifer A. Surtees\u00a031. The Detection and Analysis of Chromosome Fragile SitesVictoria A. Bjerregaard, \u00d6zg\u00fcn \u00d6zer, Ian D. Hickson, and Ying Liu\u00a032. Imaging of DNA Ultrafine Bridges in Budding YeastOliver Quevedo and Michael Lisby\u00a033. Detection of Ultra-Fine Anaphase Bridges Anna H. Bizard, Christian F. Nielsen, and Ian D. Hickson \u00a034. A Chromatin Fiber Analysis Pipeline to Model DNA Synthesis and Structures in Fission YeastSarah A. Sabatinos and Marc D. Green\u00a035. Long-term Imaging of DNA Damage and Cell Cycle Progression in Budding Yeast Using Spinning Disk Confocal MicroscopyRiccardo Montecchi and Etienne Schwob\u00a036. The CellClamper: A Convenient Microuidic Device for Time-Lapse Imaging of YeastGregor W. Schmidt, Olivier Frey, and Fabian Rudolf\u00a037. Characterization of Structural and Configurational Properties of DNA by Atomic Force Microscopy Alice Meroni, Federico Lazzaro, Marco Muzi-Falconi, and Alessandro Podest\u00e0\u00a038. Genome-wide Quantitative Fitness Analysis (QFA) of Yeast CulturesEva-Maria Holstein, Conor Lawless, Peter Banks, and David Lydall\u00a039. Rewiring the Budding Yeast Proteome using Synthetic Physical InteractionsGu\u00f0j\u00f3n \u00d3lafsson and Peter H. Thorpe\u00a040. Reporter-based Synthetic Genetic Array Analysis: a Functional Genomics Approach for Investigating Transcript or Protein Abundance Using Fluorescent Proteins in Saccharomyces cerevisiaeHendrikje G\u00f6ttert, Mojca Mattiazzi Usaj, Adam P. Rosebrock, and Brenda J. Andrews\u00a041. Statistical Analysis and Quality Assessment of ChIP-seq Data with DROMPARyuichiro Nakato and Katsuhiko Shirahige\u00a042. Quantitative Analysis of DNA Damage Signaling Responses to Chemical and Genetic PerturbationsFrancisco M. Bastos de Oliveira, Dongsung Kim, Michael Lanz, and Marcus B. Smolka","merchants_number":2,"ean":9781493973057,"category_id":103,"size":null,"min_price":168,"low_price_merchant_id":70255345,"ID":4679741,"merchants":["euniverse","weltbild"],"brand":"undefined","slug":"genome-instability","url":"\/unterhaltung\/produkt\/genome-instability\/","low_price_merchant_name":"eUniverse"}

CHF 178.00

Extracellular Vesicles

1. Extracellular Vesicles: A Brief Overview and Its Role in Precision Medicine Mingyu Shang, John Ji, Chao Song, Bao Jun Gao, Jason Gang Jin, Winston Patrick Kuo, and Hongjun Kang 2. Red Blood Cells: A Source of Extracellular Vesicles Winston Patrick Kuo, John Tigges, Vasilis Toxavidis, and Ionita Ghiran Part I: Isolation of Extracellular Vesicles ...

4139549 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvYmQvZjIvOTkvNjU1MDA1NzEwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvYmQvZjIvOTkvNjU1MDA1NzEwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2kud2VsdGJpbGQuZGUvcC9leHRyYWNlbGx1bGFyLXZlc2ljbGVzLTI3MzU0NjgzNi5qcGc=","post_title":"Extracellular Vesicles","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9781493972517&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fbiologie%2F378015%2Fextracellular-vesicles-methods-and-protocols%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"1. Extracellular Vesicles: A Brief Overview and Its Role in Precision Medicine Mingyu Shang, John Ji, Chao Song, Bao Jun Gao, Jason Gang Jin, Winston Patrick Kuo, and Hongjun Kang 2. Red Blood Cells: A Source of Extracellular Vesicles Winston Patrick Kuo, John Tigges, Vasilis Toxavidis, and Ionita Ghiran Part I: Isolation of Extracellular Vesicles 3. Isolation of Extracelullar Vesicles by Ultracentrifugation Fatemeh Momen-Heravi 4. Sequential Filtration: A Gentle Method for the Isolation of Functional Extracellular Vesicles Mitja L. Heinemann and Jody Vykoukal 5. Paper-Based Devices for Isolation of Extracellular Vesicles Yi-Hsing Hsiao and Chihchen Chen 6. Filter-Based Extracellular Vesicle mRNA Isolation and High-Throughput Gene Expression Analysis Cindy M. Yamamoto, Taku Murakami, and Shu-Wing Ng 7. Specific and Generic Isolation of Extracellular Vesicles with Magnetic Beads Ketil W. Pedersen, Bente Kierulf, and Axl Neurauter Part II: Purification of Extracellular Vesicles 8. Polymer-Based Purification of Extracellular Vesicles Peter N. Brown and Hang Yin 9. Size Exclusion Chromatography: A Simple and Reliable Method for Exosome Purification Richard Lobb and Andreas M\u00f6ller 10. Purification Protocols for Extracellular Vesicles Rebecca E. Lane, Darren Korbie, Matt Trau, and Michelle M. Hill Part III: Characterization of Extracellular Vesicles 11. Characterization of Extracellular Vesicles by Surface Plasmon Resonance Hyungsoon Im, Katherine Yang, Hakho Lee, and Cesar M. Castro 12. Extracellular Vesicle Isolation and Analysis by Western Blotting Emma J.K. Kowal, Dmitry Ter-Ovanesyan, Aviv Regev, and George M. Church 13. Analysis of Extracellular Vesicles Using Fluorescence Nanoparticle Tracking Analysis Pauline Carnell-Morris, Dionne Tannetta, Agnieszka Siupa, Patrick Hole, and Rebecca Dragovic 14. Characterization of Extracellular Vesicles by Flow Cytometry Virginia Camacho, Vasilis Toxavidis, and John C. Tigges 15. Characterization of Extracellular Vesicles by Size-Exclusion High-Performance Liquid Chromatography (HPLC) Tao Huang and Jiang He 16. Multi-Surface Antigen Staining of Larger Extracellular Vesicles Veronika Lukacs-Kornek, Henrike Julich, Sabine Katharina Urban, and Miroslaw Kornek 17. Microcapillary Chip-Based Extracellular Vesicle Profiling System Takanori Akagi and Takanori Ichiki Part IV: Imaging of Extracellular Vesicles 18. Detection and Characterization of Extracellular Vesicles by Transmission and Cryo-Transmission Electron Microscopy Petr Cizmar and Yuana Yuana 19. Imaging of Isolated Extracellular Vesicles Using Fluorescence Microscopy Dmitry Ter-Ovanesyan, Emma J.K. Kowal, Aviv Regev, George M. Church, and Emanuele Cocucci Part V: Tracking of Extracellular Vesicles 20. In Vivo Tracking of Extracellular Vesicles in Mice Using Fusion Protein Comprising Lactadherin and Gaussia Luciferase Yuki Takahashi, Makiya Nishikawa, and Yoshinobu Takakura 21. Tracking Extracellular Vesicles Delivery and RNA Translation Using Multiplexed Reporters Anthony Yan-Tang Wu and Charles Pin-Kuang Lai Part VI: Downstream Extracellular Vesicle Applications Genomics and Proteomics 22. Extraction and Analysis of Extracellular Vesicle-Associated miRNAs Following Antibody-Based Extracellular Vesicle Capture from Plasma Samples Davide Zocco and Natasa Zarovni 23. Extracellular Vesicle miRNA Detection Using Molecular Beacons Won Jong Rhee and Seunga Jeong 24. Rapid Isolation of Extracellular Vesicles from Blood Plasma with Size-Exclusion Chromatography Followed by Mass Spectrometry-Based Proteomic Profiling Simion Kreimer and Alexander R. Ivanov 25. An Adaptable Polyethylene Glycol-Based Workflow for Proteomic Analysis of Extracellar Vesicles Stephanie N. Hurwitz and David G. Meckes, Jr. Part VII: Isolation of Extracellular Vesicles from Biofluids 26. Isolation of Extracellular Vesicles from Ovarian Follicular Fluid: Evaluation of Ultracentrifugation and Commercial Kits Shlomit Kenigsberg, Clifford C. Librach, and Juliano C. da Silveira 27. Isolation of Extracellular Vesicles in Saliva Using Density Gradient Ultracentrifugation Kazuya Iwai, Satoshi Yamamoto, Mitsutaka Yoshida, and Kiyotaka Shiba 28. Isolation of Extracellular Vesicles from Breast Milk Xin Wang 29. An Integrated Double-Filtration Microfluidic Device for Detection of Extracellular Vesicles from Urine for Bladder Cancer Diagnosis Li-Guo Liang, Ye-Feng Sheng, Sherry Zhou, Fatih Inci, Lanjuan Li, Utkan Demirci, and ShuQi Wang Part VIII: Extracellular Vesicles Isolated from Cell Culture, Parasites, and Stem Cells 30. Electric Field-Induced Disruption and Releasing Viable Content from Extracellular Vesicles Chris Wang, Austin Wang, Fang Wei, David T.W. Wong, and Michael Tu 31. Production and Characterization of Extracellular Vesicles in Malaria Smart Mbagwu, Michael Walch, Luis Filgueira, and Pierre-Yves Mantel 32. Isolation of Extracellular Vesicles from Stem Cells Zixin Chen, Yongjun Li, Hong Yu, Yan Shen, Chengwei Ju, Genshan Ma, Yutao Liu, Il-man Kim, Neal L. Weintraub, and Yaoliang Tang Part IX: Extracellular Vesicles in Mouse Models 33. The Use of Peripheral Extracellular Vesicles for Identification of Molecular Biomarkers in a Solid Tumor Mouse Model Noem\u00ed Garc\u00eda-Romero, Gorjana Rackov, Cristobal Belda-Iniesta, and Angel Ayuso-Sacido Part X: Therapeutic Applications of Extracellular Vesicles 34. Therapeutic Applications of Extracellular Vesicles: Perspectives from Newborn Medicine Gareth R. Willis, Stella Kourembanas, and S. Alex Mitsialis 35. Therapeutic Use of Tumor Cell-Derived Extracellular Vesicles Jing Liu, Jingwei Ma, Ke Tang, and Bo Huang","merchants_number":2,"ean":9781493972517,"category_id":103,"size":null,"min_price":178,"low_price_merchant_id":70255345,"ID":4139549,"merchants":["euniverse","weltbild"],"brand":"undefined","slug":"extracellular-vesicles","url":"\/unterhaltung\/produkt\/extracellular-vesicles\/","low_price_merchant_name":"eUniverse"}

CHF 157.00

Oxygen Transport to Tissue XXXV

Preface.- Acknowledgements.- Remembering Professor Mamoru Tamura.- Part 1: Hypoxia.- Increased Kidney Metabolism as a Pathway to Kidney Tissue Hypoxia and Damage: Effects of Triiodothyronine and Dinitrophenol in Normoglycemic Rats.- Hypoxia-Induced Cerebral Angiogenesis in Mouse Cortex with Two-Photon Microscopy.- Reduction of Cytochrome c Oxidase During Vasovagal Hypoxia-Ischaemia in...

4907978 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvOTUvMTkvOGEvMzgwMDI4ODgwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvOTUvMTkvOGEvMzgwMDI4ODgwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2M0LXN0YXRpYy5kb2RheC5jb20vdjIvMTgwLTE4MC0xMjI5MjI3MDVfZ0tNbVhuLXBuZw==","post_title":"Oxygen Transport to Tissue XXXV","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9781461472568&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fmedizin-pharmazie%2F369561%2Foxygen-transport-to-tissue-xxxv%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"Preface.- Acknowledgements.- Remembering Professor Mamoru Tamura.- Part 1: Hypoxia.- Increased Kidney Metabolism as a Pathway to Kidney Tissue Hypoxia and Damage: Effects of Triiodothyronine and Dinitrophenol in Normoglycemic Rats.- Hypoxia-Induced Cerebral Angiogenesis in Mouse Cortex with Two-Photon Microscopy.- Reduction of Cytochrome c Oxidase During Vasovagal Hypoxia-Ischaemia in Human Adult Brain: A Case Study.- Increased HIF-1 and 2 Accumulation, but Decreased Microvascular Density, in Chronic Hyperoxia and Hypercapnia in the Mouse Cerebral Cortex.- Oxygen Delivery: The Principal Role of the Circulation.- Heart Rate Variability in Newborns with Hypoxic Brain Injury.- Part 2: Brain Oxygenation.- Simultaneous Monitoring of Brain and Skin Oxygenation during Haemorrhagic Shock in Piglets.- Hemispheric Differences of Motor Execution: A Near-Infrared Spectroscopy Study.- Acute Stress Exposure Preceding Global Brain Ischemia Accelerates Decreased Doublecortin Expression in the Rat Retrosplenial Cortex.- Effects of Transcranial Direct Current Stimulation of the Motor Cortex on Prefrontal Cortex Activation during a Neuromuscular Fatigue Task: An fNIRS Study.- The Effect of Inner Speech on Arterial CO2, Cerebral Hemodynamics and Oxygenation - A Functional NIRS Study.- Investigation of Frontal Lobe Activation with fNIRS and Systemic Changes during Video Gaming.- Effect of Valsalva Maneuver-induced Hemodynamic Changes on Brain Near-infrared Spectroscopy Measurements.- Cerebral Autoregulation in Premature Infants.- Brain Tissue Oxygen Saturation Increases during Sleep in Adolescents.- Changes of Cerebral Oxygen Metabolism and Hemodynamics during ECPR with Hypothermia Measured by Near Infrared Spectroscopy: A Pilot Study.- Part 3: Muscle Oxygenation.- Analysis of NIRS-based Muscle Oxygenation Parameters by Inclusion of Adipose Tissue Thickness.- Statistical Treatment of Oxygenation-related Data in Muscle Tissue.- O2 Saturation in the Intercostal Space during Moderate and Heavy Constant-load Exercise.- Muscle, Prefrontal and Motor Cortex Oxygenation Profiles during Prolonged Fatiguing Exercise.- Aging Affects Spatial Distribution of Leg Muscle Oxygen Saturation during Ramp Cycling Exercise.- Which is the Best Indicator of Muscle Oxygen Extraction during Exercise using NIRS? - Evidence that HHb is not the Candidate.- Tissue Oxygenation during Exercise Measured with NIRS: Reproducibility and Influence of Wavelengths.- Using Portable NIRS to Compare Arm and Leg Muscle Oxygenation during Roller-skiing in Bi-athletes: A Case Study.- The Use of Portable NIRS to measure Muscle Oxygenation and Haemodynamics during a Repeated Sprint Running Test.- Tumor Oxygenation.- Amifostine Acts upon Mitochondria to Stimulate Growth of Bone Marrow and Regulate Cytokines.- Hypoxia, Lactate Accumulation and Acidosis: Siblings Or Accomplices Driving Tumor Progression And Resistance To Therapy?.- Breast Cancer Detection of Large Size to DCIS by Hypoxia and Angiogenesis using NIRS.- Impact of Extracellular Acidosis on Intracellular pH Control and Cell Signaling in Tumor Cells.- Tumor Oxygenation: An Appraisal of Past and Present Concepts, and a Look into the Future.- In Vivo Metabolic Evaluation of Breast Tumor Mouse Xenografts for Predicting Aggressiveness Using the Hyperpolarized 13C-NMR Technique.- Mapping the Redox State of CHOP-treated Non-Hodgkin's Lymphoma Xenografts in Mice.- Maternal Bias in Mouse Radiosensitivity: The Role of the Mitochondrial PTP.- Interleukin 11 Protects Bone Marrow Mitochondria from Radiation Damage.- Tumor Reoxygenation following Administration of the EGFR inhibitor, Gefitinib, in Experimental Tumors.- Radiation Affects the Responsiveness of Bone Marrow to G-CSF.- Application of MOBILE (Mapping of Oxygen By Imaging Lipids relaxation Enhancement) to Study Variations in Tumor Oxygenation.- Primo Vascular System and its Potential Role in Cancer Metastasis.- Part 5: Cell Metabolism.- Pancreaticoduodenectomy using Perioperative Zymogen Protein C to Help Prevent Blood Clotting. A Trilogy on Increased Patient Safety.- Inhibition of Mammalian Target of Rapamycin Induces Renal Mitochondrial Uncoupling in Rats.- Molecular Hydrogen Consumption in the Human Body during the Inhalation of Hydrogen Gas.- Oxidative Metabolism: Glucose vs Ketones.- Part 6: System Modelling.- Modelling Blood Flow and Metabolism in the Piglet Brain during Hypoxia-ischaemia: Simulating pH Changes.- Modelling Blood Flow and Metabolism in the Piglet Brain during Hypoxic-ischaemia: Simulating Brain Energetics.- Mathematical Modelling of Near Infrared Spectroscopy Signals and Intracranial Pressure in Brain Injured Patients.- Dependence on NIRS Source-Detector Spacing of Cytochrome C Oxidase Response to Hypoxia and Hypercapnia in the Adult Brain.- Modeling Hemoglobin Nitrite Reductase Activity as a Mechanism of Hypoxic Vasodilation?.- Part 7: Measurement Technologies.- Development of a Hybrid Microwave-optical Tissue Oxygenation Probe to Measure Thermal Response in the Deep Tissue.- Oxygen Sensitive Quantum Dots for Possible Nano-scale Oxygen Imaging in Cultured Cells.- Boron Tracedrug Design for Neutron Dynamic Therapeutics for LDL.- New Method of Analysing NIRS Data from Prefrontal Cortex at Rest.- Radiation Oxygen Biology with Pulse Electron Paramagnetic Resonance Imaging in Animal Tumors.- Wavelength Selection for the Improvement of the Signal to Noise Ratio for Imaging of Haemoglobin Oxygenation with RGB Reflectometry.- Improving Pulse Oximetry Accuracy by Removing Motion Artifacts from Photoplethysmograms using Relative Sensor Motion: A Preliminary Study.- Measuring the Vascular Diameter of Brain Sur-face and Parenchymal Arteries in Awake Mouse.- Simultaneous Imaging of Cortical Blood Flow and Haemoglobin Concentration with LASCA and RGB Reflectometry.- Quality Evaluation Method for Rat Brain Cryofixation Based on NADH Fluorescence.- Cerebral Cortex Activation Mapping upon Electrical Muscle Stimulation by 32-channel Time Domain Functional Near Infrared Spectroscopy.- NIRS-based Neurofeedback Learning Systems for Controlling Activity of the Prefrontal Cortex.- Cortical Mapping of 3D Optical Topography in Infants.- Monitoring of Hemodynamic Change in Patients with Carotid Artery Stenosis during the Tilt Test using Wearable Near-infrared Spectroscopy.- Index.","merchants_number":2,"ean":9781461472568,"category_id":103,"size":null,"min_price":157,"low_price_merchant_id":70255345,"ID":4907978,"merchants":["euniverse","dodax"],"brand":"undefined","slug":"oxygen-transport-to-tissue-xxxv","url":"\/unterhaltung\/produkt\/oxygen-transport-to-tissue-xxxv\/","low_price_merchant_name":"eUniverse"}

CHF 239.00

Autophagy

Part I: Autophagry In Vitro1. Recombinant Expression, Purification and Assembly of p62 FilamentsAbul K. Tarafder, Audrey Guesdon, Tanja Kuhm, and Carsten Sachse 2. Structural Studies of Autophagy-related ProteinsMelanie Schwarten, Oliver H. Weiergräber, Dusan Petrovic, Birgit Strodel, and Dieter Willbold 3. Structural Studies of Mammalian Autophagy Lipidation ComplexKazuto Ohashi, Chi...

5522405 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvMDEvY2EvN2EvNzI4MTc5ODQwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvMDEvY2EvN2EvNzI4MTc5ODQwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2kud2VsdGJpbGQuZGUvcC9hdXRvcGhhZ3ktMjczNTgyOTU1LmpwZw==","post_title":"Autophagy","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9781493988723&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fbiologie%2F378784%2Fautophagy-methods-and-protocols%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"Part I: Autophagry In Vitro1. Recombinant Expression, Purification and Assembly of p62 FilamentsAbul K. Tarafder, Audrey Guesdon, Tanja Kuhm, and Carsten Sachse\u00a02. Structural Studies of Autophagy-related ProteinsMelanie Schwarten, Oliver H. Weiergr\u00e4ber, Dusan Petrovic, Birgit Strodel, and Dieter Willbold\u00a03. Structural Studies of Mammalian Autophagy Lipidation ComplexKazuto Ohashi, Chinatsu Otomo, Zoltan Metlagel, and Takanori Otomo\u00a04. Structural Studies of Selective Autophagy in YeastAkinori Yamasaki, Yasunori Watanabe and Nobuo N. Noda\u00a05. Biophysical Studies of LC3 Family Proteins\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 Javier H. Herv\u00e1s, Zuri\u00f1e Ant\u00f3n, and Alicia Alonso \u00a0 6. Reconstituting Autophagy Initiation from Purified Components Peter Mayrhofer and Thomas Wollert\u00a07. Cell-free Reconstitution of Autophagic Membrane FormationMin Zhang and Liang Ge\u00a08. Use of Peptide Arrays for Identification and Characterization of LIR MotifsMads Skytte Rasmussen, \u00c5sa Birna Birgisdottir and Terje Johansen\u00a09. Studying Autophagic Lysosome Reformation in Cells and by an in vitro Reconstitution SystemYang Chen, Qian Peter Su, and Li Yu\u00a010. Formation of Autophagosomes Coincides With Relaxation of Membrane CurvatureJaime Agudo-Canalejo and Roland L. Knorr\u00a0 11. Studies of Receptor-Atg8 Interactions during Selective Autophagy Christine Abert and Sascha Martens \u00a0Part II: Imaging Autophagy in Tissue Culture12. Correlative Light and Electron Miscopy of Autophagosomes Sigurdur Gudmundsson, Jenny Kahlhofer, Nastassia Baylac, Katri Kallio, and Eeva-Liisa Eskelinen\u00a013. Improved Electron Microscopy (EM) Fixation Methods for Tracking Autophagy-associated Membranes in Cultured Mammalian CellsRitsuko Arai and Satoshi Waguri\u00a014. 3-color Simultaneous Live Imaging of Autophagy-related StructuresMaho Hamasaki, Hiroyuki Ueda, Ouin Kunitaki, \u00a0and Tamotsu Yoshimori\u00a015. Correlative Live-cell Imaging and Super-resolution Microscopy of Autophagy Eleftherios Karanasios\u00a016. Methods for Imaging Autophagosome Dynamics in Primary NeuronsAudrey Dong, Vineet Vinay Kulkarni, and Sandra Maday\u00a017. Imaging Autophagy in hiPSC-derived Midbrain Dopaminergic Neuronal Cultures for Parkinson's Disease ResearchStathakos, P., Jimenez-Moreno, N., Crompton, L., Nistor, P, Caldwell, M.A., and Lane, J.D\u00a018. Correlative Light Electron Microscopy to analyze LC3 Proteins in Caenorhabditis elegans embryoC\u00e9line Largeau and Renaud Legouis\u00a019. Imaging Non-canonical Autophagy and LC3-associated Phagocytosis in Cultured CellsElise Jacquin, Katherine Fletcher, and Oliver Florey\u00a0Part III: Assays to Measure (and Screen For) Autophagy and Related Processes20. Measurement of Bulk Autophagy by a Cargo Sequestration AssayNikolai Engedal, Morten Luhr, Paula Szalai, and Per O. Seglen\u00a021. Methods to Detect Loss of Lysosomal Membrane Integrity Sonja Aits\u00a022. Monitoring of Autophagy and Cell Volume Regulation in Kidney Epithelial Cells in Response to Fluid Shear StressMaria M. Lazari, Idil Orhon, Patrice Codogno, and Nicolas Dupont\u00a023. Identification and Regulation of Multimeric Protein Complexes in Autophagy via SILAC- based Mass Spectrometry ApproachesSt\u00e9phanie Kaeser-Pebernard, Britta Diedrich, and J\u00f6rn Dengjel\u00a024. Identification and Validation of Novel Autophagy Regulators using an Endogenous Readout siGENOME ScreenMaria New, Tim Van Acker, Ming Jiang, Rebecca Saunders, Jaclyn S. Long, Jun-ichi Sakamaki, Kevin M. Ryan, Michael Howell, and Sharon A. Tooze\u00a025. Autophagy Pathway Mapping to Elucidate the Function of Novel Autophagy Regulators Identified by High-throughput ScreeningMartina Wirth1 and Sharon A. Tooze\u00a026. In vitro Screening Platforms for Identifying Autophagy Modulators in Mammalian CellsElena Seranova, Carl Ward, Miruna Chipara, Ratul Banerjee, Tatiana R. Rosenstock, and Sovan Sarkar\u00a027. In vitro Screening Platforms for Identifying Autophagy Modulators in Mammalian CellsElena Seranova, Carl Ward, Miruna Chipara, Ratul Banerjee, Tatiana R. Rosenstock, and Sovan Sarkar\u00a028. Methods for the Study of Entotic Cell DeathJens C. Hamann, Sung Eun Kim, and Michael Overholtzer\u00a029. MHC Class I Internalization via Autophagy ProteinsMonica Loi, Laure-Anne Ligeon and Christian M\u00fcnz\u00a0Part IV: Measuring and Imaging Autophagy In Vitro30. Analysis of Autophagy for Liver PathogenesisNazmul Huda, Hui Zou, Shengmin Yan, Bilon Khambu, and Xiao-Ming Yin\u00a031. Autophagy in 3D In Vitro and Ex Vivo Cancer ModelsCarlo Follo, Dario Barbone, William G. Richard2, Raphael Bueno, and V. Courtney Broaddus\u00a032. Autophagy in PlateletsMeenakshi Banerjee , Yunjie Huang, Madhu M. Ouseph , Smita Joshi , Irina Pokrovskaya , Brian Storrie , Jinchao Zhang , Sidney W. Whiteheart , and Qing Jun Wang\u00a033. Methods to Image Macroautophagy in the Brain In VivoXigui Chen, Kanoh Kondo, and Hitoshi Okazawa\u00a034. Measuring Nonselective and Selective Autophagy in the LiverTakashi Ueno and Masaaki Komatsu\u00a035. Measuring Autophagy in PancreatitisAlejandro Ropolo, Daniel Grasso, and Maria I. Vaccaro\u00a036. Characterization of the \"autophagic flux\" in Prostate Cancer Tissue Biopsies by LC3A\/LAMP2a Immunofluorescence and Confocal MicroscopyKalamida D., Giatromanolaki A., and Koukourakis M.I\u00a037. Methods to Determine the Role of Autophagy Proteins in C. elegans AgeingSivan Henis-Korenblita and Alicia Mel\u00e9ndez\u00a0\u00a0Part V: Mitophagy and Other Selective Autophagy Pathways38. Investigating Non-selective Autophagy in DrosophilaSzabolcs Tak\u00e1ts, Sarolta T\u00f3th, Gy\u00f6z\u00f6 Szenci, and G\u00e1bor Juh\u00e1sz\u00a039. Imaging the Dynamics of Mitophagy in Live CellsAndrew S. Moore and Erika L.F. Holzbaur\u00a040. Triggering Mitophagy with Photosensitizers Cheng-Wei Hsieh and Wei Yuan Yang\u00a041. Investigating Mitophagy and Mitochondrial Morphology in vivo using mito-QCThomas G. McWilliams and Ian G. Ganley\u00a042. Assays to Monitor Mitophagy in Drosophila Panagiotis Tsapras, Anne-Claire Jacomin, and Ioannis P.\u00a0 Nezis\u00a043. Mitophagy Dynamics in Caenorhabditis elegansKonstantinos Palikaras, Eirini Lionaki, and Nektarios Tavernarakis\u00a044. Methods for Studying Mitophagy in YeastPanagiota Kolitsida and Hagai Abeliovich\u00a045. Measuring Anti-bacterial AutophagyKeith B Boyle and \u00a0Felix Randow\u00a046. Quantitative Phosphoproteomics of Selective Autophagy ReceptorsThomas Juretschke, Petra Beli, and Ivan Dikic\u00a047. Analysis of Chaperone-mediated AutophagyY.R. Juste and A.M. Cuervo\u00a048. Interactive Autophagy: Monitoring a Novel Form of Selective Autophagy by Macroscopic ObservationsJana Petri and Roland L. Knorr","merchants_number":2,"ean":9781493988723,"category_id":103,"size":null,"min_price":239,"low_price_merchant_id":70255345,"ID":5522405,"merchants":["euniverse","weltbild"],"brand":"undefined","slug":"autophagy","url":"\/unterhaltung\/produkt\/autophagy\/","low_price_merchant_name":"eUniverse"}

CHF 211.00

Systems Biology of Alzheimer's Disease

Part I: Systems Biology of Multifactorial Diseases: Alzheimer's Disease 1. Alzheimer's as a Systems-Level Disease Involving the Interplay of Multiple Cellular Networks Juan I. Castrillo and Stephen G. Oliver 2. Application of Systems Theory in Longitudinal Studies on the Origin and Progression of Alzheimer's Disease Simone Lista, Zaven S. Khachaturian, Dan Rujesc...

4833908 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvNjEvNTMvZDEvNTE0NDczMjAwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvNjEvNTMvZDEvNTE0NDczMjAwMDAwMUFfNjAweDYwMC5qcGc=","post_title":"Systems Biology of Alzheimer's Disease","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9781493926268&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fmedizin-pharmazie%2F376198%2Fsystems-biology-of-alzheimer-s-disease%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"Part I: Systems Biology of Multifactorial Diseases: Alzheimer's Disease 1. Alzheimer's as a Systems-Level Disease Involving the Interplay of Multiple Cellular Networks Juan I. Castrillo and Stephen G. Oliver 2. Application of Systems Theory in Longitudinal Studies on the Origin and Progression of Alzheimer's Disease Simone Lista, Zaven S. Khachaturian, Dan Rujescu, Francesco Garaci, Bruno Dubois, and Harald Hampel Part II: Alzheimer's Disease: Main Underlying Pathways and Networks 3. The APP Proteolytic System and Its Interactions with Dynamic Networks in Alzheimer's Disease Sally Hunter, Steven Martin, and Carol Brayne 4. Effects of Mild and Severe Oxidative Stress on BACE1 Expression and APP Amyloidogenic Processing Jiangli Tan, Qiao-Xin Li, and Genevieve Evin 5. Advanced Assay Monitoring APP-Carboxyl-Terminal Fragments as Markers of APP Processing in Alzheimer Disease Mouse Models Ana Garc\u00eda-Osta and Mar Cuadrado-Tejedor 6. Advanced Optical Super-Resolution Method and Techniques for the Study of beta-Amyloid Aggregation In Vitro and In Vivo Dorothea Pinotsi, Gabriele S. Kaminski Schierle, and Clemens F. Kaminski 7. Protocols for Monitoring the Development of Tau Pathology in Alzheimer's Disease Alberto R\u00e1bano, Raquel Cuadros, Paula Merino-Serr\u00e1is, Izaskun Rodal, Ruth Benavides-Piccione, Elena G\u00f3mez, Miguel Medina, Javier DeFelipe, and Jes\u00fas Avila 8. LC3-II Tagging and Western Blotting for Monitoring Autophagic Activity in Mammalian Cells Anne Streeter, Fiona M. Menzies, and David C. Rubinsztein 9. Advanced Mitochondrial Respiration Assay for Evaluation of Mitochondrial Dysfunction in Alzheimer's Disease Amandine Grimm, Karen Schmitt, and Anne Eckert 10. Analysis of Microglial Proliferation in Alzheimer's Disease Diego Gomez-Nicola and V. Hugh Perry Part III: Comprehensive Disease Models Recapitulating Alzheimer's Disease Features: From Cellular Models to Human 11. Yeast as a Model for Alzheimer's Disease: Latest Studies and Advanced Strategies Mathias Verduyckt, H\u00e9l\u00e8ne Vignaud, Tine Bynens, Jeff Van den Brande, Vanessa Franssens, Christophe Cullin, and Joris Winderickx 12. Yeast as a Model for Studies on Abeta Aggregation Toxicity in Alzheimer's Disease, Autophagic Responses, and Drug Screening Afsaneh Porzoor and Ian Macreadie 13. Drosophila melanogaster as a Model for Studies on the Early Stages of Alzheimer's Disease Jung Yeon Lim, Stanislav Ott, and Damian C. Crowther 14. Chronic Mild Stress Assay Leading to Early Onset and Propagation of Alzheimer's Disease Phenotype in Mouse Models Mar Cuadrado-Tejedor and Ana Garc\u00eda-Osta 15. Gene Expression Studies on Human Trisomy 21 iPSCs and Neurons: Towards Mechanisms Underlying Down's Syndrome and Early Alzheimer's Disease-Like Pathologies Jason P. Weick, Huining Kang, George F. Bonadurer III, and Anita Bhattacharyya 16. Cortical Differentiation of Human Pluripotent Cells for In Vitro Modeling of Alzheimer's Disease Nathalie G. Saurat, Frederick J. Livesey, and Steven Moore Part IV: Experimental Systems Biology: Next Generation Molecular and High-Throughput Methods for the Study of Disease Susceptibility and Networks Dynamics Interplay in Complex Diseases 17. Next Generation Sequencing in Alzheimer's Disease Lars Bertram 18. Pooled-DNA Sequencing for Elucidating New Genomic Risk Factors, Rare Variants Underlying Alzheimer's Disease Sheng Chih Jin, Bruno A. Benitez, Yuetiva Deming, and Carlos Cruchaga 19. New Genome-Wide Methods for Elucidation of Candidate Copy Number Variations (CNVs) Contributing to Alzheimer's Disease Heritability Kinga Szigeti 20. RNA-Sequencing to Elucidate Early Patterns of Dysregulation Underlying the Onset of Alzheimer's Disease Bei Jun Chen, James D. Mills, Caroline Janitz, and Michael Janitz 21. Systems Biology Approaches to the Study of Biological Networks Underlying Alzheimer's Disease: Role of miRNAs Wera Roth, David Hecker, and Eugenio Fava 22. The Emerging Role of Metalloproteomics in Alzheimer's Disease Research Dominic J. Hare, Alan Rembach, and Blaine R. Roberts 23. Redox Proteomics in Human Biofluids: Sample Preparation, Separation and Immunochemical Tagging for Analysis of Protein Oxidation Fabio Di Domenico, Marzia Perluigi, and D. Allan Butterfield 24. Advanced Shotgun Lipidomics for Characterization of Altered Lipid Patterns in Neurodegenerative Diseases and Brain Injury Miao Wang and Xianlin Han 25. AlzPathway, an Updated Map of Curated Signaling Pathways: Towards Deciphering Alzheimer's Disease Pathogenesis Soichi Ogishima, Satoru Mizuno, Masataka Kikuchi, Akinori Miyashita, Ryozo Kuwano, Hiroshi Tanaka, and Jun Nakaya Part V: Computational Systems Biology, Network biology: Next Generation Computational and Integrative Network Biology Approaches for the Study of Modules, Network Dynamics, and Their Interplay in Complex Diseases 26. A Computational Network Biology Approach to Uncover Novel Genes Related to Alzheimer's Disease Andreas Zanzoni 27. Network Approaches to the Understanding of Alzheimer's Disease: From Model Organisms to Humans Justin Yerbury, Dan Bean, and Giorgio Favrin 28. Characterization of Genetic Networks Associated with Alzheimer's Disease Bin Zhang, Linh Tran, Valur Emilsson, and Jun Zhu 29. Network-Based Analysis for Uncovering Mechanisms Underlying Alzheimer's Disease Masataka Kikuchi, Soichi Ogishima, Akinori Miyashita, Ryozo Kuwano, Jun Nakaya, and Hiroshi Tanaka 30. The SDREM Method for Reconstructing Signaling and Regulatory Response Networks: Applications for Studying Disease Progression Anthony Gitter and Ziv Bar-Joseph Part VI: Systems Biology of Alzheimer's Disease in Practice: From Systems Biology to Early Diagnostics and Systems Medicine 31. Advanced Neuroimaging Methods Towards Characterization of Early Stages of Alzheimer's Disease Jorge Sepulcre and Joseph C. Masdeu 32. Plasma Proteomics Biomarkers in Alzheimer's Disease: Latest Advances and Challenges Robert Perneczky and Liang-Hao Guo 33. A Practical Guide For Exploring Opportunities of Repurposing Drugs for CNS Diseases in Systems Biology Hongkang Mei, Gang Feng, Jason Zhu, Simon Lin, Yang Qiu, Yue Wang, and Tian Xia","merchants_number":1,"ean":9781493926268,"category_id":103,"size":null,"min_price":211,"low_price_merchant_id":70255345,"ID":4833908,"merchants":["euniverse"],"brand":"undefined","slug":"systems-biology-of-alzheimers-disease","url":"\/unterhaltung\/produkt\/systems-biology-of-alzheimers-disease\/","low_price_merchant_name":"eUniverse"}

Arterial Chemoreceptors in Physiology and Pathophysiology

CHF 157.00

Arterial Chemoreceptors in Physiology and Pathophysiology

1. Preface C Peers & P Kumar 2. Epigenetic regulation of Carotid Body Oxygen Sensing: Clinical Implications J. Nanduri, N. R. Prabhakar 3. Experimental observations on the biological significance of hydrogen sulfide in carotid body chemoreception. T.Gallego-Martin, T. Agapito, M. Ramirez, E. Olea, S. Yubero, A. Rocher, A. Gomez-Nin o, A. Obe...

4879118 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvMjMvOTQvZWQvNTIwNzU4NzAwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvMjMvOTQvZWQvNTIwNzU4NzAwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2M0LXN0YXRpYy5kb2RheC5jb20vdjIvMTgwLTE4MC0xMjI5NDU2ODZfNVJZanZWLXBuZw==","post_title":"Arterial Chemoreceptors in Physiology and Pathophysiology","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9783319184395&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fmedizin-pharmazie%2F443680%2Farterial-chemoreceptors-in-physiology-and-pathophysiology%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"1. Preface C Peers & P Kumar 2. Epigenetic regulation of Carotid Body Oxygen Sensing: Clinical Implications J. Nanduri, N. R. Prabhakar 3. Experimental observations on the biological significance of hydrogen sulfide in carotid body chemoreception. T.Gallego-Martin, T. Agapito, M. Ramirez, E. Olea, S. Yubero, A. Rocher, A. Gomez-Nin o, A. Obeso, C. Gonzalez 4. The CamKKbeta inhibitor STO609 causes artefacts in calcium imaging and selectively inhibits BKCa in mouse carotid body type I cells. J. G. Jurcsisn, R. L. Pye, J. Ali, B. L. Barr and C. N. Wyatt 5. Tissue dynamics of the carotid body under chronic hypoxia: a computational study A. Porzionato, D. Guidolin, V. Macchi, G. Sarasin, A. Mazzatenta, C. Di Giulio, J. Lopez-Barneo, R. De Caro 6. Paracrine Signaling in Glial-like Type II cells of the Rat Carotid Body S. Murali, M. Zhang, C. A. Nurse 7. Selective mi and opioid agonists inhibit voltage-gated Ca2+ entry in isolated rat carotid body type I cells E. M. Ricker, R. L. Pye, B. L. Barr, C. N. Wyatt 8. Measurement of ROS levels and membrane potential dynamics in the intact carotid body ex vivoA. Bernardini, U. Brockmeier, E. Metzen, U. Berchner-Pfannschmidt, E. Harde, A. Acker-Palmer, D. Papkovsky, H. Acker, J. Fandrey 9. Acutely administered leptin increases [Ca2+]i and changes membrane conductance via modulation of BKCa channels in rat carotid body type I cells R.L. Pye, E.J. Dunn, E.M. Ricker, B.L. Barr, C.N. Wyatt \\ 10. Functional properties of mitochondria in the type-1 cell and their role in oxygen sensing K.J. Buckler & P.J. Turner 11. Potentiation of hypoxic pulmonary vasoconstriction by hydrogen sulfide precursors 3-mercaptopyruvate and D-cysteine is blocked by the cystathione g lyase inhibitor propargylglycineJ. Prieto-Lloret & P. I. Aaronson 12. Modulation of the LKB1-AMPK signalling pathway underpins hypoxic pulmonary vasoconstriction and pulmonary hypertensionA.M. Evans, S.A. Lewis, O.A. Ogunbayo, J. Moral-Sanz 13. Organismal Responses to Hypoxemic Challenges R.S. Fitzgerald, G.A. Dehghani, S. Kiihl 14. Effect of lipopolysacchride (LPS) exposure on structure and function of the carotid body in newborn rats Z.R. Master, K. Kesavan, A. Mason, M. Shirahata, E.B. Gauda 15. Hypoxic Ventilatory Reactivity in Experimental Diabetes M. Pokorski, M. Pozdzik, J. Antosiewicz, A. Dymecka, A. Mazzatenta, C. Di Giulio16. Adenosine receptor blockade by caffeine inhibits carotid sinus nerve chemosensory activity in chronic intermittent hypoxic animals J.F. Sacramento, C. Gonzalez, M.C. Gonzalez-Martin and S.V. Conde17. Neurotrophic properties, chemosensory responses and neurogenic niche of the human carotid body P Ortega-S\u00e1enz, J Villadiego, R Pardal, JJ Toledo-Aral and J L\u00f3pez-Barneo18. Is the carotid body a metabolic monitor? M. Shirahata, W-Y Tang, M.-K. Shin, V. Polotsky 19. Lipopolysaccharide-induced ionized hypocalcemia and acute kidney injury in carotid chemo\/baro-denervated rats R. Ferna ndez, P. Corte s, R. del Ri o, C. Acun a-Castillo, E.P. Reyes20. Role of the Carotid Body Chemoreflex in the Pathophysiology of Heart Failure: APerspective from Animal Studies H.D. Schultz, N. J. Marcus & R. Del Rio21. A short-term fasting in neonates induces breathing instability and epigenetic modification in the carotid bodyW.-Y. Tang, E. Kostuk, M. Shirahata22. Carotid Body Chemoreflex Mediates Intermittent Hypoxia-Induced Oxidative Stress in the Adrenal Medulla G.K. Kumar, Y-J. Peng, J. Nanduri, N.R. Prabhakar 23. The association between antihypertensive medication and blood pressure control in patients with obstructive sleep apneaL.N. Diogo, P. Pinto, C. B\u00e1rbara, A.L. Papoila, E.C. Monteiro24. An overview on the respiratory stimulant effects of caffeine and progesterone on response to hypoxia and apnea frequency in developing rats A. Bairam, N.P. Uppari, S. Mubayed, V. Joseph 25. Hyperbaric oxygen therapy improves glucose homeostasis in type 2 diabetes patients: a likely involvement of the carotid bodies P. Vera-Cruz, F. Guerreiro, M.J. Ribeiro, M.P. Guarino, S.V. Conde26. Possible role of TRP channels in rat glomus cells I. Kim, L. Fite, D. F. Donnelly, J. H. Kim, J. L. Carroll27. Nitric oxide deficit is part of the maladaptive paracrine-autocrine response of the carotid body to intermittent hypoxia in sleep apnea M.L. Fung 28. Respiratory control in the mdx mouse model of Duchenne muscular dystrophy D. Burns, D. Edge, D. O'Malley, K.D. O'Halloran29. Mild chronic intermittent hypoxia in Wistar rats evokes significant cardiovascular pathophysiology but no overt changes in carotid body-mediated respiratory responses C. J. Ray, B. Dow, P. Kumar, A.M. Coney30. Crucial role of the carotid body chemoreceptors on the development of high arterial blood pressure during chronic intermittent hypoxiaR. Iturriaga, D.C. Andrade, R. Del Rio31. Relative contribution of nuclear and membrane progesterone receptors in respiratory control R. Boukari, F. Marcouiller, V. Joseph32. Inhibition of protein kinases AKT and ERK1\/2 reduce the carotid body chemoreceptor response to hypoxia in adult ratsJ. P. Iturri, V. Joseph, G. Rodrigo, A. Bairam, J. Soliz33. Ecto-5'-nucleotidase, adenosine and transmembrane adenylyl cyclase signalling regulate basal carotid body chemoafferent outflow and establish the sensitivity to hypercapnia. A.P.S. Holmes, A.R. Nunes, M.J. Cann, P.Kumar34. T-type Ca2+ channel regulation by CO: a mechanism for control of cell proliferation H. Duckles, M.M. Al-Owais, J. Elies, E. Johnson, H.E. Boycott, M.L. Dallas, K.E. Porter, J.P. Boyle, J. L. Scragg, C. Peers35. Glutamatergic Receptor Activation in the Commisural Nucleus Tractus Solitarii (cNTS) Mediates Brain Glucose Retention (BGR) Response to Anoxic Carotid Chemoreceptor (CChr) Stimulation in Rats R. Cue llar, S. Montero, S. Luqui n, J. Garci a-Estrada, O. Dobrovinskaya, V. Melnikov, M. Lemus, E. Roces de A lvarez-Buyll36. Enhanced Serotonin (5HT) secretion in pulmonary neuroepithelial bodies from PHD-1 null mice S. Livermore, J. Pan, H. Yeger, P. Ratcliffe, T. Bishop, E. Cutz 37. Selective expression of galanin in type I cells of the human carotid body C. Di Giulio, G.D. Marconi, S. Zara, A. Di Tano, A. Porzionato, M. Pokorski, A. Cataldi, V. Macchi , A.Mazzatenta 38. Role of BK channels in murine carotid body neural responses in vivo. L.E. Pichard, C.M. Crainiceanu, P. Pashai, E.W. Kostuk, A. Fujioka, M. Shirahata 39. Chronic intermittent hypoxia blunts the expression of ventilatory long term facilitation in sleeping rats D. Edge, KD. O'Halloran 40. Heme oxygenase-1 influences apoptosis via CO-mediated inhibition of K+ channels. M.M. Al-Owais, M.L. Dallas, J.P. Boyle, J. L. Scragg , C. Peers 41. Inhibition of T-type Ca2+ channels by hydrogen sulfide J. Elies, JL Scragg, M. Dallas, D. Huang, S. Huang, JP Boyle, N. Gamper, C. Peers 42. GAL-021 and GAL-160 are efficacious in rat models of obstructive and central sleep apnea and inhibit BKCa in isolated rat carotid body glomus cells M. Dallas, C. Peers, F.J. Golder, S. Baby, R. Grube, D.E. MacIntyre 43. The human carotid body gene expression and function in signaling of hypoxia and inflammationJ. K\u00e5hlin, S. Mkrtchian, A. Ebberyd, L. I. Eriksson, M. J. Fagerlund 44. The Carotid Body Does Not Mediate The Acute Ventilatory Effects Of LeptinE. Olea, M.J. Ribeiro, T.Gallego-Martin, S. Yubero, R. Rigual, JF. Masa, A. Obeso, S. V. Conde, C. Gonzalez 45. Concluding RemarksE. Gauda","merchants_number":2,"ean":9783319184395,"category_id":103,"size":null,"min_price":157,"low_price_merchant_id":70255345,"ID":4879118,"merchants":["euniverse","dodax"],"brand":"undefined","slug":"arterial-chemoreceptors-in-physiology-and-pathophysiology","url":"\/unterhaltung\/produkt\/arterial-chemoreceptors-in-physiology-and-pathophysiology\/","low_price_merchant_name":"eUniverse"}

Circulating Nucleic Acids in Serum and Plasma - CNAPS IX

CHF 211.00

Circulating Nucleic Acids in Serum and Plasma - CNAPS IX

Foreword Peter B. Gahan, Michael Fleischhacker, Bernd Schmidt .- Part I Nucleic Acids in Oncology - prognosis, treatments screening and metastases .- 1 Circulating Cell-free miR-373, miR-200a, miR-200b and miR-200c in Patients with Epithelial Ovarian Cancer Xiaodan Meng, Volkmar Müller, Karin Milde-Langosch, Fabian Trillsch, Klaus Pantel, Heidi Schwarzenbach.- 2 Cell-free miRNA-141...

4174511 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvY2EvMzAvYWEvNTgxNzUzOTQwMDAwMUFfNjAweDYwMC5qcGc=!aHR0cHM6Ly9vczEubWVpbmVjbG91ZC5pby9iMTAxNTgvbWVkaWEvaW1hZ2UvY2EvMzAvYWEvNTgxNzUzOTQwMDAwMUFfNjAweDYwMC5qcGd8fnxodHRwczovL2kud2VsdGJpbGQuZGUvcC9jaXJjdWxhdGluZy1udWNsZWljLWFjaWRzLWluLXNlcnVtLWFuZC1wbGFzbWEtY25hcHMtMzI4MDA3NjMyLmpwZw==","post_title":"Circulating Nucleic Acids in Serum and Plasma - CNAPS IX","deeplink":"https:\/\/cct.connects.ch\/tc.php?t=116298C1969900829T&subid=9783319420424&deepurl=https%3A%2F%2Feuniverse.ch%2Fbuecher%2Fmathematik-naturwissenschaft-technik%2Fmedizin-pharmazie%2F450406%2Fcirculating-nucleic-acids-in-serum-and-plasma-cnaps-ix%3FsPartner%3Dtoppreise","labels":[],"brand_id":1,"post_content":"Foreword Peter B. Gahan, Michael Fleischhacker, Bernd Schmidt .- Part I\u00a0\u00a0 Nucleic Acids in Oncology - prognosis, treatments screening and metastases .- 1 Circulating Cell-free miR-373, miR-200a, miR-200b and miR-200c in Patients with Epithelial Ovarian Cancer Xiaodan Meng, Volkmar M\u00fcller, Karin Milde-Langosch, Fabian Trillsch, Klaus Pantel, Heidi Schwarzenbach.- 2 \u00a0Cell-free miRNA-141 and miRNA-205 as Prostate Cancer Biomarkers Ivan D. Osipov, Ivan A. Zaporozhchenko, Anna A. Bondar, Marat M. Zaripov, Vladimir E. Voytsitskiy, Valentin V. Vlassov, Pavel P. Laktionov, Evgeny S. Morozkin.- 3 Clinical utility of circulating tumor DNA for molecular assessment and precision medicine in pancreatic cancer Erina Takai, Yasushi Totoki, Hiromi Nakamura, Mamoru Kato, Tatsuhiro Shibata, Shinichi Yachida.- 4 An Enquiry Concerning the Characteristics of Cell-free DNA Released by Cultured Cancer Cells \u00a0Abel J Bronkhorst, Johannes F Wentzel, Janine Aucamp, Etresia van Dyk, Lissinda du Plessis, Piet J Pretorius .-\u00a05 Detection of p53 Mutations in Circulating DNA of Transplanted Hepatocellular Carcinoma Patients as a Biomarker of Tumor Recurrence Noelia Garc\u00eda-Fern\u00e1ndez , Hada Macher, Amalia Rubio, Pilar Jim\u00e9nez-Arriscado, Bernal-Bellido C,\u00a0 Bellido-D\u00edaz ML, Gonzlo Su\u00e1rez-Artacho, Juan M. Guerrero, Miguel A. G\u00f3mez-Bravo, Patrocinio Molinero .- 6 Unbiased Detection of Somatic Copy Number Aberrations in cfDNA of Lung Cancer Cases and High-risk Controls with Low Coverage Whole Genome sequencing Fiona Taylor, James Bradford, Penella J. Woll, Dawn Teare, Angela Cox.- 7 Liquid Profiling in Lung Cancer - Quantification of Extracellular miRNAs in Bronchial Lavage Bernd Schmidt, Grit Rehbein, Michael Fleischhacker.- 8 Screening of KRAS Mutation in Pre- and Post-surgery Serum of Patients Suffering from Colon Cancer by COLD-PCR HRM Elena Trujillo-Arribas, Hado C. Macher, Pilar Jim\u00e9nez-Arriscado, Fernando de la Portilla, Patrocinio Molinero, Juan M. Guerrero, Amalia Rubio.- 9 Non-Dividing Cell Virtosomes Affect in vitro and in vivo Tumour Cell Replication Mariano Garcia-Arranz, Damian Garcia-Olmo, Luz Vega-Clemente, Maurice Stroun, Peter B. Gahan.- \u00a010 Features of Circulating DNA Fragmentation in Blood of Healthy Females and Breast Cancer Patients Svetlana N. Tamkovich, Natalia A. Kirushina, Vladimir E. Voytsitskiy, Pavel P. Laktionov.- 11 Liquid Profiling of Circulating Nucleic Acids as a Novel Tool for the Management of Cancer Patients Stefan Holdenrieder.- Part II CNAPS in foetal medicine.- 12 Characterization of Human Pregnancy Specific Glycoprotein (PSG) Gene Copy Number Variations in Pre-eclampsia Patients Chia Lin Chang, Chia Yu Chang,\u00a0\u00a0Da Xian Lee, Po Jen Cheng.- 13 Non-Invasive Prenatal Diagnosis of Fetal-Maternal Platelet Incompatability by Cold High Resolution Melting Analysis Marta Ferro, Hada C. Macher, Pilar Noguerol, Pilar Jimenez-Arriscado, Patrocinio Molinero, Juan M. Guerrero, Amalia Rubio.- 14 Implementing Non-invasive Prenatal Diagnosis (NIPD) in a National Health Service Laboratory, from Dominant to Recessive Disorders Suzanne Drury, Sarah Mason, Fiona McKay, Kitty Lo, Christopher Boustred, Lucy Jenkins, Lyn S Chitty.- Part III\u00a0 \u00a0BIOLOGY OF CNAPS.- 15 Comparative Analysis of Harmful Physical Factors Effects on the Genome of the Cell Irina N. Vasilyeva, Valery N. Zinkin, Vladimir G. Bespalov.- 16 Heterochromatic Tandem Repeats in the Extracellular DNA Olga I. Podgornaya, Irina N. Vasilyeva, Vladimir G. Bespalov.- 17 A Historical and Evolutionary Perspective on Circulating Nucleic Acids and Extracellular Vesicles: Circulating Nucleic Acids as Homeostatic Genetic Entities Janine Aucamp, Abel J Bronkhorst. Piet J Pretorius .- 18 Comparison of microRNA Content in Plasma and Urine Indicates the Existence of a Transrenal Passage of Selected microRNAs Eva Pazourkova, Sarka Pospisilova, Iveta Svobodova, Ales Horinek, Antonin Brisuda, Viktor Soukup,Jan Hrbacek, Otakar Capoun, Jaroslav Mares, Tomas Hanus, Marek Babjuk, Marie Korabecna.- 19 A Quantitative Assessment of Cell-free DNA Utilizing Several Housekeeping Genes: Measurements from Four Different Cell Lines Janine Aucamp, Abel Bronkhorst, Johannes F. Wentzel , Piet Pretorius.- 20 Oligodeoxynucleotide Analogues of Circulating DNA Inhibit dsRNA-induced Immune Response at the Early Stages of Signal Transduction Cascade in a Cell Type-dependent Manner Anna V. Cherepanova, Zhanna K. Nazarkina, Pavel P. Laktionov.- 21 GC-rich DNA Fragments and Oxidized Cell-free DNA Have Different Effects on NF-kB and NRF2 Signaling in MSC \u00a0Vasilina A. Sergeeva, Svetlana V. Kostyuk, Elizaveta S. Ershova, Elena M. Malinovskaya, Tatiana D. Smirnova, Larisa V. Kameneva, Natalia N. Veiko.- 22 Evaluation of the State of Transplanted Liver health by Monitoring of Organ-specific genomic Marker in Circulating DNA from Receptor Hada C. Macher, Gonzalo Su\u00e1rez-Artacho, Pilar Jim\u00e9nez-Arriscado, Sara \u00c1lvarez-G\u00f3mez, Noelia Garc\u00eda-Fern\u00e1ndez, Juan M. Guerrero, Patrocinio Molinero, Elena Trujillo-Arribas , Miguel A. G\u00f3mez-Bravo, Amalia Rubio.- 23 Vesicular and extra-vesicular RNAs of Human Blood Plasma Anna V. Savelyeva, Dmitriy N. Baryakin, Elena D. Chikova, Elena V. Kuligina, Vladimir A. Richter, Dmitriy V. Semenov.- 24 Artificial Analogues of Circulating Box C\/D RNAs Induce strong Innate Immune Response and microRNA Activation in Human Adenocarcinoma CellsGrigory A. Stepanov, Julia A. Filippova, Anna A. Nushtaeva, Elena V. Kuligina, Olga A. Koval, Vladimir A. Richter, and Dmitriy V. Semenov.-25 Multiple Ways of cfDNA Reception and Following ROS Production in Endothelial Cells\u00a0Anna Y. Alekseeva, Larisa V. Kameneva, Svetlana V. Kostyuk and Natalia N. Veiko.- 26 Protein Content of Circulating Nucleoprotein ComplexesSvetlana N. Tamkovich,, Oleg S. Tutanov, Danil S. Serdukov, Maxim S. Belenikin, Anatoliy G. Shlikht, Natalia A. Kirushina, Tatiana G. Duzhak, Vladimir E. Voytsitskiy, Yuri P. Tsentalovich, Pavel P. Laktionov.- Part IV Methodology.- 27 Digital PCR of Genomic Rearrangements for Monitoring Circulating Tumour DNAHongdo Do, Daniel Cameron, Ramyar Molania Bibhusal Thapa, Gareth Rivalland, Paul L Mitchell, Carmel Murone, Thomas John, Tony Papenfuss, Alexander Dobrovic.- 28 MFast-SeqS as a Monitoring and Prescreening Tool for Tumour-specific Aneuploidy in Plasma DNA\u00a0Methodological Variables in the Analysis of Cell-free DNA Jelena Belic, Marina Koch, Peter Ulz, Martina Auer, Teresa Gerhalter, Sumitra Mohan, Katja Fischereder, Edgar Petru, Thomas Bauernhofer5, Jochen B. Geigl, Michael R. Speicher, Ellen Heitzer.- 29 Methodological Variables in the Analysis of Cell-free DNA\u00a0Abel J. Bronkhorst, Janine Aucamp, Piet J. Pretorius .- 30 Novel Technology for Enrichment of\u00a0 Biomolecules from Cell-Free Body Fluids and Subsequent DNA Sizing Vipulkumar Patel, Peter Celec, Magdalena Grunt, Heidi Schwarzenbach, Ingo Jenneckens, Timo Hillebrand.- 31 A Rapid and Sensitive Method for Detection of the T790M Mutation of EGFR in Plasma DNA Hideharu Kimura, Shingo Nishikawa, Hayato Koba, Taro Yoneda, Takashi Sone, Kazuo Kashara.- 32 Evaluation of Different Blood Collection Tubes and Blood Storage Conditions for the Preservation and Stability of Cell-free Circulating DNA for the Analysis of the Methylated mSEPT9 Colorectal Cancer Screening Marker Jurgen Distler, ReimoTetzner, Gunter Weiss, Thomas K\u00f6nig, Anne Schlegel, Michal Bagrowski.- 33 Purification of Circulating Cell-Free DNA from Plasma and Urine Using the Automated Large-Volume Extraction on the QIAsymphony SP Instrument Alexander Wolf, Katharina Beller, Sebastian Groemminger, Wera Hofmann, Matthias Sachse, Jana Fassunke.- 34 Detection and Quantification of KIT mutations in ctDNA by Plasma Safe-SeqS Johannes Fredebohm, Daniel Mehnert, Ann-Kathrin L\u00f6ber, Frank Holtrup, Vanessa van Rahden, Philipp Angenendt, Frank Diehl.- Part V Ethics.- 35 Lost in translation? Ethical challenges of implementing a new diagnostic procedure Dagmar Schmitz.- Part VI\u00a0 Round-table.- 36 Academia meets Industry General Discussion between panel and audience.\u00a0","merchants_number":2,"ean":9783319420424,"category_id":103,"size":null,"min_price":211,"low_price_merchant_id":70255345,"ID":4174511,"merchants":["euniverse","weltbild"],"brand":"undefined","slug":"circulating-nucleic-acids-in-serum-and-plasma-cnaps-ix","url":"\/unterhaltung\/produkt\/circulating-nucleic-acids-in-serum-and-plasma-cnaps-ix\/","low_price_merchant_name":"eUniverse"}

CHF 122.50

Three-Dimensional Nanoarchitectures

1. Building Three dimensional Nanostructured Devices by Self-Assembly by Steve Hu, Jeong-Hyun Cho and David H. GraciasSummary1.1.0 The pressing need for three dimensional patterned nanofabrication1.2.0 Self-assembly using molecular linkages1.2.1 Three dimensional self-assembly using protein linkages1.2.2 Three dimensional self-assembly with DNA linkages1.3.0 Three dimensional self-ass...

5030498 {"price-changing":0,"image":"https:\/\/image.vergleiche.ch\/small\/aHR0cHM6Ly9jNC1zdGF0aWMuZG9kYXguY29tL3YyLzE4MC0xODAtMTIyMzk1MDUxXzVSTHBYRC1wbmc=!aHR0cHM6Ly9jNC1zdGF0aWMuZG9kYXguY29tL3YyLzE4MC0xODAtMTIyMzk1MDUxXzVSTHBYRC1wbmd8fnxodHRwczovL29zMS5tZWluZWNsb3VkLmlvL2IxMDE1OC9tZWRpYS9pbWFnZS8wNy8wZi9jNy8yOTQ1OTAwNTAwMDAxQV82MDB4NjAwLmpwZw==","post_title":"Three-Dimensional Nanoarchitectures","deeplink":"https:\/\/www.awin1.com\/pclick.php?p=28276712429&a=401125&m=11816&pref1=9781441998217","labels":[],"brand_id":1,"post_content":"1. Building Three dimensional Nanostructured Devices by Self-Assembly by Steve Hu, Jeong-Hyun Cho and David H. GraciasSummary1.1.0 The pressing need for three dimensional patterned nanofabrication1.2.0 Self-assembly using molecular linkages1.2.1 Three dimensional self-assembly using protein linkages1.2.2 Three dimensional self-assembly with DNA linkages1.3.0 Three dimensional self-assembly using physical forces1.4.0 Three dimensional patterned nanofabrication by curving and bending nanostructures1.4.1 Curving hingeless nanostructures using stress1.4.2 Three dimensional nanofabrication by bending hinged panels to create patterned polyhedral nanoparticles1.5.0 ConclusionsAcknowledgementsReferences 2. Bio-inspired Three-Dimensional Nanoarchitectures by Jian Shi and Xudong Wang2.1 Introduction2.2 Historical Perspective2.3 Bio-inspired Nanophotonics2.3.1 Photonic Crystals2.3.2 Color Mine in Nature2.3.3 Natural Photonic Crystals2.4 Bio-inspired Fabrication of Nanostrctures2.4.1 Biomineralization2.4.2 Biological Fine Structure Duplication2.5 Bio-inspired Functionality2.6 ConclusionReferences3. Building 3D Micro- and Nanostructures through Nanoimprint by Xing Cheng3.1 Introduction to 3D structure fabrication through nanoimprint3.2 Overview of nanoimprint lithography3.2.1 Fundamentals of nanoimprint lithography3.2.2 Materials for nanoimprint lithography]3.3 Building 3D Nanostructures by Nanoimprint3.3.1 Direct patterning of 3D structures in one step3.3.1.1 Replicating 3D polymer structures from 3D templates3.3.1.2 Applications of 3D polymer structures by one-step nanoimprint3.3.2 Building 3D nanostructures by transfer bonding and sequential layer stacking3.3.2.1 Principles of transfer bonding and sequential layer stacking3.3.2.2 3D structures built by transfer bonding and sequential layer stacking3.3.2.3 Defect modes and process yield of transfer bonding and sequential layer stacking3.3.3 Building 3D nanostructures by two consecutive nanoimprints3.4 Summary and future outlookReferences 4. Electrochemical Growth of Nanostructured Materials by Jin-Hee Lim and John B. Wiley4.1 Magnetic Nanomaterials4.2 Semiconductor Nanostructures4.3 Thermoelectric Nanomaterials4.4 Conducting Polymer Nanostructures4.5 Nanotube and Core-Shell Nanostructures4.6 Porous Au Nanowires4.7 Modification of Nanowires4.8 Functionalization of Nanowires4.9 Nanostructure Arrays on Substrates4.10 Patterning of NanowiresAcknowledgment5. Three dimensional micro\/nanomaterials generated by fiber drawing nanomanufacturing by Zeyu Ma, Yan Hong, Shujiang Ding, Minghui Zhang, Maniul Hossain, Ming Su5.1 Introduction5.2 Fiber draw tower5.3 Materials selections5.4 Drawing process5.5 Size design5.6 3D assembling5.7 Metallic nanowires5.8 Semiconductor nanowires5.9 Glass microchannel array5.10 Differential etching of glasses5.11 Glass microspike array5.12 Hybrid glass membranes5.13 Textured structure of encapsulated paraffin wax microfiber5.14 ConclusionsReferences6.0 One-Dimensional Metal Oxide Nanostructures for Photoelectrochemical Hydrogen Generation by Yat Li6.1 Introduction6.1.1 Photoelectrochemical hydrogen generation6.1.2 Challenges in Metal Oxide based PEC hydrogen generation6.1.3 One-Dimensional Nanomaterials for Photoelectrodes6.2 Pristine Metal Oxide Nanowire\/Nanotube-Arrayed Photoelectrodes6.2.1 Nanowire arrayed photoelectrodes6.2.1.1 Hematite ( -Fe2O3)6.2.1.2. Titanium Oxide (TiO2) and Zinc Oxide (ZnO)6.2.1.3. Tungsten Trioxide (WO3)6.2.2 Nanotube arrayed photoelectrodes6.3 Element-Doped Metal Oxide 1D Nanostructures6.3.1 TiO2 nanostructures6.3.2. ZnO nanostructures6.3.3 Hematite ( -Fe2O3) nanostructures6.4 Quantum Dot Sensitizations6.4.1 Background6.4.2 Quantum Dot Sensitized ZnO Nanowires6.4.3 Quantum Dot Co-Sensitized Nanowires6.4.4 Double-sided Quantum Dot Sensitization6.5 Synergistic Effect of Quantum Dot Sensitization and Elemental Doping6.6 Concluding RemarksReferences 7. Helical Nanostructures: Synthesis and Potential Applications by Pu-Xian Gao and Gang Liu7.1 Introduction7.2 Semiconductor nanohelices7.2.1 ZnO nanohelices7.2.1.1 Superlattice-structured ZnO nanohelices7.2.1.2 Superelasticity, nanobuckling and non-linear electronic transport properties of superlattice-structured ZnO nanohelices7.2.1.2.1 Superelasticity of superlattice-structured ZnO nanohelix7.2.1.2.2 Nanobuckling and fracture of superlattice-structured ZnO nanohelix7.2.1.2.3 Non-linear electronic transport of superlattice-structured ZnO nanohelix7.2.1.3 Other ZnO nanohelices7.2.4 InP nanohelices7.2.2 SiO2 nanohelices7.2.3 CdS nanohelices7.2.4 InP nanohelices7.2.5 Ga2O3 nanohelices7.3 Carbon-related nanohelices7.3.1 Helical carbon nanoribbon\/nanocoil7.3.2 Helical carbon nanotube7.3.3 Tungsten-containing carbon (WC) nanospring7.4 Other nanohelices7.4.1 Helical SiC\/SiO2 core-shell nanowires and Si3N4 microcoils7.4.2 MgB2 nanohelices7.4.3 Si spirals7.5 Potential applications7.6 SummaryAcknowledgementReferences 8. Hierarchical 3D Nanostructure Organization for Next Generation Devices by Eric N. Dattoli and Wei Lu8.1 Introduction8.2 Fluidic Flow - Assisted Assembly8.2.1 Drop-Drying8.2.2 Channel-Confined Fluidic Flow8.2.3 Blown Bubble Film Transfer8.3 Nematic Liquid Crystal - Induced Assembly8.4 Langmuir-Blodgett Assembly8.5 Dielectrophoresis - Assembly8.6 Chemical Affinity and Electrostatic Interaction - directedAssembly8.7 Contact Transfer8.7.1 Shear-assisted Contact Printing8.7.2 Stamp Transfer8.8 Directed Growth8.8.1 Horizontal Growth8.8.2 Vertical Growth8.9 Device Applications8.9.1 Thin-Film Transistor8.9.1.1 Performance considerations for NW- or NT- based TFTs8.9.1.2 Transparent Nanowire-based TFTs8.9.1.3 CNT-based TFTs8.9.2 3D, Multilayer Device Structures8.9.3 Sensors8.9.4 Vertical Nanowire Field Effect Transistors (FETs)8.10 ConclusionReferences 9. Strain-induced Self Rolled-up Semiconductor Microtube Resonators: A New Architecture for Photonic Device Applications by Xin Miao, Ik Su Chun, and Xiuling Li9.1 Introductions9.2 Formation Process9.3 Photonic Applications of Rolled-up Semiconductor Tubes9.3.1 Spontaneous emission from quantum well microtubes: intensity enhancement and energy shift9.3.2 Optical resonance modes in rolled-up microtube ring cavity9.3.3 Optically pumped lasing from rolled-up microtube ring cavity 10. Carbon Nanotube Arrays: Synthesis, Properties and Applications by Suman Neupane, Wenzhi Li10.1 Introduction10.2 Carbon Nanotube Synthesis10.2.1 Arc discharge10.2.2 Laser ablation10.2.3 Electrochemical synthesis10.2.4 Diffusion flame synthesis10.2.5 Chemical vapor deposition10.3 Carbon Nanotube Arrays10.3.1 CNTA synthesis using patterned catalyst arrays10.3.1.1 Pulsed laser deposition10.3.1.2 Anodic aluminum oxide (AAO) templates10.3.1.3 Reverse micelle method10.3.1.4 Photolithography10.3.1.5 Electrochemical etching10.3.1.6 Sputtering10.3.1.7 Nanosphere lithography10.3.1.8 Sol-gel method10.3.2 CNTA synthesis by other methods10.3.3 Horizontal arrays of CNTs10.4 Mechanical Properties10.5 Thermal Properties10.6 Electrical properties10.7 Applications of CNTs and CNTAs10.7.1 Hydrogen storage10.7.2 CNTs as Sensors10.7.3 CNTs for battery and supercapacitor applications10.7.4 CNTs for photovoltaic device10.8 ConclusionsReferences 11. Molecular Rotors Observed by Scanning Tunneling Microscopy by Ye-liang Wang, Qi Liu, Hai-gang Zhang, Hai-ming Guo, Hong-jun GaoAbstract11.1 Introduction11.2 Solution-based and surface-mounted molecule machines11.3 Single molecular rotors at surfaces11.3.1 A monomolecular rotor in supramolecular network11.3.2 Gear-like rotation of molecular rotor along the edge of molecular island11.3.3 Thermal-driven rotation on reconstructed-surface template 11.3.4 STM-driven rotation on reconstructed-surface template11.3.5 Molecular rotors with variable rotation radii11.3.6 Rolling motion of a single molecule at surface11.4 Array of molecular motors at surfaces11.5 Outlook11.6 ConclusionAcknowledgementsReferences 12. Nanophotonic Devices Based on ZnO Nanowires by Qing Yang and Zhong Lin Wang12.1 Introduction12.2 Pure optical devices based on ZnO NWs12.2.1 ZnO NW subwavelength waveguides and their applications12.2.2 Optical pumped lasers in ZnO NWs12.2.3 Nonlinear optical devices based on ZnO NWs12.3 Optoelectronic devices based ZnO NWs12.3.1 ZnO NW ultra-sensitive UV and Infrared PDs12.3.2 Dye-sensitized solar cells based on ZnO NWs12.3.3 Single ZnO NW and NW array light emitting diodes12.3.4 Electrically pumped random lasing from ZnO nanorod arrays12.4 Piezo-phototronic devices based on ZnO NWs12.4.1 Optimizing the power output of a ZnO photocell by piezopotential12.4.2 Enhancing Sensitivity of a Single ZnO Micro-\/NW Photodetector by Piezo-phototronic effect12.5 ConclusionsReferences 13. Nanostructured Light Management for Advanced Photovoltaics by Jia Zhu, Zongfu Yu, Sangmoo Jeong, Ching-Mei Hsu, Shanui Fan, Yi CuiAbstract13.1 Introduction13.2 Fabrication of Nanowire and Nanocone Arrays13.2.1 Method13.2.2 Shape Control: Nanowires and Nanocones13.2.3 Diameter and Spacing Control13.2.4 Large Scale Process13.3 Photon Management: Anti-reflection13.3.1 Nanowires13.3.2 Nanocones13.4 Photon Management: Absorption Enhancement13.4.1 Different Mechanisms13.4.2 Nanodome Structures13.5 Solar Cell performance13.6 Fundamental Limit of Light-trapping in Nanophotonics13.7 Summary and OutlookReferences 14. Highly Sensitive and Selective Gas Detection by 3D Metal Oxide Nanoarchitectures by Jiajun Chen, Kai Wang, Baobao Cao, Dr. Weilie Zhou14.1 Introduction14.2 Highly Sensitive Gas Detection by Standalone 3D Nanosensors14.2.1 Metal Oxide Nanowire \/ Nanotube Array Gas Sensors14.2.1.1 Nanowire Arrays14.2.1.2 Nanotube Arrays14.2.2 Gas Sensors Based on Opal and Inverted Opal Nanostructures14.3 Sensor Arrays Based on 3D Nanostructured Gas Sensors14.4 Conclusion RemarksAcknowledgementReferences 15. Quantum Dot Sensitized Three Dimensional Nanostructures for Photovoltaic Applications by Jun Wang, Xukai Xin, Daniel Vennerberg, Zhiqun Lin15.1 Introduction15.2 Quantum dot sensitized solar cells15.2.1 Overview15.2.2 Synthesis of quantum dots and surface functionalization15.2.3 Quantum dot sensitized nanoparticle films15.2.4 Quantum dot sensitized nanowire arrays15.2.5 Quantum dot sensitized nanotube arrays15.2.6 Investigation of charge injection in quantum dot sensitized solar cells15.2.6.1 Generation of excited electrons15.2.6.2 Recombination and transportation of excited electrons15.3 OutlookReferences 16. Three Dimensional Photovoltaic Devices Based on Vertically Aligned Nanowire Array by Kai Wang, Jiajun Chen, Satish Chandra Rai, and Weilie Zhou16.1 Introduction16.2 Photovoltaic devices based on heteroepitaxial-grown nanowire array integrated with the substrate16.3 Photovoltaic devices based on axial nanowire array16.4 Photovoltaic devices based on nanowire array embedded in thin film16.5 Photovoltaic devices based on nanowire array with core-shell structure16.5.1 P-N core-shell homojuntion photovoltaic devices16.5.2 Type II core-shell heterojuntion photovoltaic devices16.5.2.1 Synthesis of ZnO\/ZnSe and ZnO\/ZnS core-shell nanowire array16.5.2.2 Structural and optical properties of ZnO\/ZnSe core-shell nanowire array16.5.2.3 Photoresponse of ZnO\/ZnSe nanowire array16.5.2.4 Morphologies, structure and optical properties of ZnO\/ZnS nanowire array16.5.2.5 Photovoltaic effect of ZnO\/ZnS nanowire array16.6. Summary and perspectivesAcknowledgementsReferences 17. Supercapacitors Based on 3D Nanostructrued Electrodes by Hao Zhang, Gaoping Cao, Yusheng Yang17.1 Supercapacitors17.2 Electrochemical double layer capacitors based on 3D Nanostructrued electrodes17.2.1 Electrodes based on activated carbons and activated carbon fibers: powdered carbons with disordered pore structures17.2.2 Electrodes based on carbon foams, carbon areogels, and other monolithic carbon: monolithic carbon with disordered micropores17.2.3 Electrodes based on template carbons, graphene, carbide-derived carbons, and hierarchical porous carbons: powdered carbons with high mesopore ratios or reasonable PSD17.2.4 Electrodes based on carbon nanotubes: monolithic carbons with developed mesoporous structures17.3 Pseudocapacitors based on 3D Nanostructrued electrodes17.3.1 Nanostructured metal oxide electrode materials17.3.2 Nanostructured conducting polymer electrodes materials17.4 Hybrid capacitors based on 3D Nanostructrued electrodes17.4.1 Nanostructured electrodes based on metal oxides\/carbon composite17.4.2 Nanostructured electrodes based on polymers\/carbon composites17.5 Conclusions and perspectivesReferences 18. Aligned Ni Coated Single Wall Carbon Nanotubes under Magnetic Field for Coolant Applications by Haiping Hong and Mark Horton18.1 Introduction18.2 Experimental18.3 Results and Discussion18.3.1 Thermal Conductivity of Nanofluids Containing Ni-coated Nanotubes18.3.2 Evidence of Magnetic Alignment of Ni-coated Nanotubes18.4 Conclusion18.5 AcknowledgementsReferences","merchants_number":2,"ean":9781441998217,"category_id":103,"size":null,"min_price":122.5,"low_price_merchant_id":1087639,"ID":5030498,"merchants":["dodax","euniverse"],"brand":"undefined","slug":"three-dimensional-nanoarchitectures","url":"\/unterhaltung\/produkt\/three-dimensional-nanoarchitectures\/","low_price_merchant_name":null}

zum Shop zum Shop

« Zurück 1…54 5556