Kundenservice/Kontakt

Fachbereiche
Buchreihen (90)	1259
Geisteswissenschaften	2245
Naturwissenschaften	5309
Mathematik	223
Informatik	310
Physik	971
Chemie	1346
Geowissenschaften	130
Humanmedizin	241
Zahn-, Mund- und Kieferheilkunde	10
Veterinärmedizin	98
Pharmazie	147
Biologie	812
Biochemie, Molekularbiologie, Gentechnologie	114
Biophysik	25
Ernährungs- und Haushaltswissenschaften	44
Land- und Agrarwissenschaften	992
Forstwissenschaften	202
Gartenbauwissenschaft	18
Umweltforschung, Ökologie und Landespflege	145
Ingenieurwissenschaften	1712
Allgemein	91
Leitlinien Unfallchirurgie 5. Auflage bestellen

Erweiterte Suche

Advanced Diffusion Studies of Active Enzymes and Nanosystems

Printausgabe
EUR 63,48

E-Book
EUR 45,48

Advanced Diffusion Studies of Active Enzymes and Nanosystems

Jan-Philipp Günther (Autor)

Vorschau

Leseprobe, PDF (120 KB)
Inhaltsverzeichnis, PDF (85 KB)

ISBN-13 (Printausgabe)	9783736973640
ISBN-13 (E-Book)	9783736963641
Sprache	Englisch
Seitenanzahl	190
Umschlagkaschierung	glänzend
Auflage	1
Erscheinungsort	Göttingen
Promotionsort	Stuttgart
Erscheinungsdatum	03.02.2021
Allgemeine Einordnung	Dissertation
Fachbereiche	Physik Physik der Atome, Moleküle, Gase und Plasmen Chemie Physikalische Chemie Biophysik
Schlagwörter	Enzyme, Alkalische Phosphatase, Aldolase, Urease, ATP Synthase, F1-ATPase, Viren, M13 Bakteriophagen, Physikalische Chemie, Biophysikalische Chemie, Aktive Materie, Aktive Diffusion, Erhöhte Diffusion, Selbstphorese, Selbstdiffusiophorese, Diffusionsmessungen, Fluoreszenzkorrelationsspektroskopie, FCS, FCCS, Fluoreszenzlöschung, Kernspinresonanzspektroskopie, NMR, PFG-NMR, Spin-Relaxation, Partikelverfolgung, Konvektion, Regime kleiner Reynolds-Zahlen, Schwimmen, Selbstantrieb, Homogene Katalyse, Click Chemie, Molekulare Katalysatoren, Artefakt, Fehlinterpretation, Enzym-Phagen-Kolloid, Enzymatische Mikropumpe, Nanosysteme, Biohybridsysteme, Biokonjugation, Selbstassemblierung, Enzymes, alkaline phosphatase, aldolase, urease, ATP synthase, F1-ATPase, virus, M13 bacteriophage, physical chemistry, biophysical chemistry, active matter, active diffusion, enhanced diffusion, self-phoresis, self-diffusiophoresis, diffusion measurements, fluorescence correlation spectroscopy, FCS, FCCS, fluorescence quenching, nuclear magnetic resonance spectroscopy, NMR, PFG-NMR, spin relaxation, particle tracking, convection, low Reynolds number regime, swimming, self-propulsion, homogenous catalysis, click chemistry, molecular catalysts, artefact, misinterpretation, enzyme-phage-colloid, enzymatic micropump, nanosystem, biohybrid system, bioconjugation, self-assembly, Brownsche Bewegung, Nanoskala, Feldgradienten, Pulse Sequences, Pulssequenzen
URL zu externer Homepage	https://pf.is.mpg.de/

Beschreibung

Enzymes are fascinating chemical nanomachines that catalyze many reactions, which are essential for life. Studying enzymes is therefore important in a biological and medical context, but the catalytic potential of enzymes also finds use in organic synthesis. This thesis is concerned with the fundamental question whether the catalytic reaction of an enzyme or molecular catalyst can cause it to show enhanced diffusion. Diffusion measurements were performed with advanced fluorescence correlation spectroscopy (FCS) and diffusion nuclear magnetic resonance (NMR) spectroscopy techniques. The measurement results lead to the unraveling of artefacts in enzyme FCS and molecular NMR measurements, and thus seriously question several recent publications, which claim that enzymes and molecular catalysts are active matter and experience enhanced diffusion. In addition to these fundamental questions, this thesis also examines the use of enzymes as biocatalysts. A novel nanoconstruct – the enzyme-phage-colloid (E-P-C) – is presented, which utilizes filamentous viruses as immobilization templates for enzymes. E-P-Cs can be used for biocatalysis with convenient magnetic recovery of enzymes and serve as enzymatic micropumps. The latter can autonomously pump blood at physiological urea concentrations.