Structural analysis of organometallic deprotonation agents and computational studies on formally hypervalent molecules / Strukturuntersuchungen organometallischer Deprotonierungsreagenzien und computerchemische Untersuchungen an formal hypervalenten Molekülen

Merkel, Sebastian

19 January 2010

No description available.

540 Chemie

Mathematics and Computer Science

Organometallverbindungen

Röntgenstrukturanalyse

Hypervalenz

QTAIM

ELI

organometallic reagents

X-ray

hypervalency

QTAIM

ELI

35.11

35.42

35.44

35.60

35.90

SFC 000 SP 000

STJ 250: Lithium {Anorganische Chemie}

STK 500: Zink {Anorganische Chemie}

Pyrazolat-liganden mit zwei facial tridentaten Koordinationstaschen - Metallkomplexe und erste Reaktivitätsuntersuchungen / Pyrazole based ligands with two facial tridentate coordination pockets - metal complexes and first investigations of reactivity

Müller, Holger

01 November 2007

No description available.

540 Chemie

Mathematics and Computer Science

Pyrazolat Liganden

facial tridentat

Kupfer(II)-Komplexe

Kupfer(I)-Komplexe

Nickelkomplexe

Magnetische Eigenschaften

ferromagetisch

antiferromagnetisch

Speziesverteilung

pyrazolate

facial tridentate

copper(II) complex

copper(I) complex

nickel complex

magnetic properties

ferromagnetic

antiferromagnetic

species distribution

35.20

35.45

35.49

35.79

STJ 550: Kupfer {Anorganische Chemie}

SOC 250: Metallkomplexe

Chelate {Chemie: Verbindungstypen}

SHS 000: Magnetochemie

STR 300: Nickel {Anorganische Chemie}

Biomimetische Oxidationsreaktionen mit zweikernigen Kupferpyrazolatkomplexen / Biomimetic oxidation reactions with dinuclear copper pyrazolate complexes

Ackermann, Jens

04 November 2003

No description available.

540 Chemie

Mathematics and Computer Science

biomimetisch

dinuklear

Katalyse

Typ 3 Kupferzentrum

Catecholase-Reaktion

Kupfersauerstoffaddukt

biomimetic

dinuclear

catalysis

type 3 copper centre

catecholase reaction

copper dioxygen adduct

35.13

35.17

35.43

35.79

SGK 100: Homogene Katalyse {Chemie}

SOC 250: Metallkomplexe

Chelate {Chemie: Verbindungstypen}

STJ 550: Kupfer {Anorganische Chemie}

Cyclopentadienyl Free Compounds of p, d, and f Elements / Cyclopentadienyl freie Komplexe von p, d und f Elementen

Neculai, Dante

08 May 2003

No description available.

30 Chemie

STL 450

STJ 250

STN 200

STL 150

STN 450

Mathematics and Natural Science

b-diketiminato liganden

Lanthanide

Aluminium

Vanadium

Cp-freie bis-hydrocarbyl Komplexe

monoalumoxane

b-diketiminato ligands

lanthanide

aluminum

vanadium

Cp-free bis-hydrocarbyl complexes

monoalumoxane

35.60

35.43

35.42

Leaflet Material Selection for Aortic Valve Repair

Abessi, Ovais

21 November 2013

Leaflet replacement in aortic valve repair (AVr) is associated with increased long-term repair failure. Hemodynamic performance and mechanical stress levels were investigated after porcine AVr with 5 types of clinically relevant replacement materials to ascertain which material(s) would be best suited for repair. Porcine aortic roots with intact aortic valves were placed in a left-heart simulator mounted with a high-speed camera for baseline valve assessment. Then, the non-coronary leaflet was excised and replaced with autologous porcine pericardium (APP), glutaraldehyde-fixed bovine pericardial patch (BPP; Synovis™), extracellular matrix scaffold (CorMatrix™), or collagen-impregnated Dacron (HEMASHIELD™). Hemodynamic parameters were measured over a range of cardiac outputs (2.5–6.5L/min) post-repair. Material properties of the above materials along with St. Jude Medical™ Pericardial Patch with EnCapTM Technology (SJM) were determined using pressurization experiments. Finite element models of the aortic valve and root complex were then constructed to verify the hemodynamic characteristics and determine leaflet stress levels. This study demonstrates that APP and SJM have the closest profiles to normal aortic valves; therefore, use of either replacement material may be best suited. Increased stresses found in BPP, HEMASHIELD™, and CorMatrix™ groups may be associated with late repair failure.

AI: aortic insufficiency APP

APP: autologous porcine pericardium

AS: aortic stenosis

AV: aortic valve

AVR: aortic valve replacement

BPP: bovine pericardial patch

CT-A: computed tomography angiography

FE: finite element

GOA: geometric orifice area

LVOT: left-ventricular outflow tract

LVW: left ventricular work

MRI: magnetic resonance imaging

STJ: sino-tubular junction

SJM: St-Jude Medical

TEE: transesophageal echography

VC: valve closing speed

VO: valve opening speed

VSC: valve slow closing speed

Leaflet Material Selection for Aortic Valve Repair

Abessi, Ovais

January 2013

Leaflet replacement in aortic valve repair (AVr) is associated with increased long-term repair failure. Hemodynamic performance and mechanical stress levels were investigated after porcine AVr with 5 types of clinically relevant replacement materials to ascertain which material(s) would be best suited for repair. Porcine aortic roots with intact aortic valves were placed in a left-heart simulator mounted with a high-speed camera for baseline valve assessment. Then, the non-coronary leaflet was excised and replaced with autologous porcine pericardium (APP), glutaraldehyde-fixed bovine pericardial patch (BPP; Synovis™), extracellular matrix scaffold (CorMatrix™), or collagen-impregnated Dacron (HEMASHIELD™). Hemodynamic parameters were measured over a range of cardiac outputs (2.5–6.5L/min) post-repair. Material properties of the above materials along with St. Jude Medical™ Pericardial Patch with EnCapTM Technology (SJM) were determined using pressurization experiments. Finite element models of the aortic valve and root complex were then constructed to verify the hemodynamic characteristics and determine leaflet stress levels. This study demonstrates that APP and SJM have the closest profiles to normal aortic valves; therefore, use of either replacement material may be best suited. Increased stresses found in BPP, HEMASHIELD™, and CorMatrix™ groups may be associated with late repair failure.

AI: aortic insufficiency APP

APP: autologous porcine pericardium

AS: aortic stenosis

AV: aortic valve

AVR: aortic valve replacement

BPP: bovine pericardial patch

CT-A: computed tomography angiography

FE: finite element

GOA: geometric orifice area

LVOT: left-ventricular outflow tract

LVW: left ventricular work

MRI: magnetic resonance imaging

STJ: sino-tubular junction

SJM: St-Jude Medical

TEE: transesophageal echography

VC: valve closing speed

VO: valve opening speed

VSC: valve slow closing speed

Syntheses and Electron Density Determination of Novel Polyimido Sulfur Ylides / Synthesen und Elektronendichtebestimmung an neuen Polyimido-Schwefelyliden

Deuerlein, Stephan

31 October 2007

No description available.

540 Chemie

Mathematics and Computer Science

Schwefelylide

Organolithiumchemie

Ladungsdichte

Bindung

QTAIM

ylidisch

ylenisch

Metallcomplexe

Zinn

Magnesium

Arsen

Schwefel

Stickstoff

Kohlenstoff

Lithium

Imide

Januskopf-Ligand

homobimetallische Komplexe

Komplexchemie

Polymorphie

sulfur ylides

organolithium chemistry

charge density

bonding

QTAIM

ylidic

ylenic

metal complexes

tin

magnesium

arsenic

sulfur

nitrogen

carbon

lithium

imides

janus-head ligand

homobimetallic complexes

complex chemistry

polymorphism

35.11

35.44

35.60

35.90

SP 000: Strukturchemie

SOC 250: Metallkomplexe

Chelate {Chemie: Verbindungstypen}

STJ 250: Lithium {Anorganische Chemie}

STO 270: Schwefeloxyde