Leiden, Netherlands : , : Brill, , 2015

©2015

90-04-27521-5

1 online resource (372 p.)

Philosophy of Religion, , 2210-481X ; ; Volume 4

230.092

Religion - Philosophy

Gnosticism

Philosophical theology

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Preliminary Material / Corneliu C. Simuț -- Introduction / Corneliu C. Simuț -- 1 The Idea of Creation / Corneliu C. Simuț -- 2 The Image of Lucifer / Corneliu C. Simuț -- 3 The Structure of Dualism / Corneliu C. Simuț -- 4 The Overlapping of Spirit and Matter / Corneliu C. Simuț -- 5 The Connection between Philosophy and Religion / Corneliu C. Simuț -- Concluding Remarks. Baur’s Synthesis of Böhme and Hegel: Gnosis as a Christian Philosophy of Religion in History / Corneliu C. Simuț -- Bibliography / Corneliu C. Simuț -- Index / Corneliu C. Simuț.

In this book, Professor Simuț shows how Christian theology started to be understood as a Gnostic philosophy of religion in the thought of the 19th-century scholar F. C. Baur. Although Baur was seen traditionally as a theologian and biblical exegete, Simuț argues that he was in fact a philosopher of religion, and it was his philosophical reading of Christian theology that informed his biblical preoccupations. Specifically, Baur’s perspective on Christian theology was heavily influenced by Jakob Böhme’s esoteric theosophy and Hegel’s religious philosophy in some key issues such as creation, Lucifer, dualism and the connection between spirit and matter coupled with that between philosophy and religion.

Chichester, United Kingdom, : Wiley, 2009

1-282-13816-2

9786612138164

0-470-74344-1

0-470-74343-3

1 online resource (684 p.)

HeysJ. R (J. Richard)

MoeniusThomas

547.2

572.36

572/.36

Organic compounds - Synthesis

Radiolabeling

Tritium

Carbon - Isotopes

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Preparation of Compounds Labeled with Tritium and Carbon-14; Contents; Preface; Glossary; Author Biographies; 1 Introduction; 1.1 Physical Properties of Tritium and Carbon-14; 1.2 Purification; 1.3 Analysis; 1.3.1 Chemical Identity; 1.3.2 Chemical (and Enantiomeric) Purity; 1.3.3 Radiochemical (and Radionuclidic) Purity; 1.3.4 Specific Activity; 1.3.5 Position of Label; 1.4 Stability and Storage of Compounds Labeled with Tritium or Carbon-14; 1.5 Specialist Techniques and Equipment; References; 2 Strategies for Target Preparation; 2.1 Formulating Target Specifications

2.2 Planning Radiotracer Preparations2.2.1 The Construction Strategy; 2.2.2 Reconstitution Strategies; 2.2.3 The Derivatization Strategy; 2.2.4 Selection of an Appropriate Strategy; 2.2.5 Case Studies of Strategy Development; References; 3 Preparation of Tritium-Labeled Compounds by Isotope Exchange Reactions; 3.1 Homogeneous Acid-

or Base-Catalyzed Exchange; 3.1.1 Exchange without Added Acid or Base; 3.1.2 Exchange under Acidic Conditions; 3.1.3 Exchange under Basic Conditions; 3.2 Heterogeneous Catalysis with Tritium in Solvent; 3.2.1 Metals; 3.2.2 Other Catalysts

3.3 Heterogeneous Catalysis in Solution with Tritium Gas3.3.1 Metal Catalysts with Nonreducible Substrates in Aqueous Solution; 3.3.2 Metal Catalysts with Nonreducible Substrates in Organic Solvents; 3.3.3 Other Catalysts; 3.3.4 Metal Catalysts with Reducible Substrates; 3.4 Homogeneous Catalysis in Solution with Tritiated Water; 3.4.1 Exchange Catalyzed by Metal Salts; 3.4.2 Exchange Catalyzed by Organoruthenium Complexes; 3.4.3 Exchange Catalyzed by Iridium Dionates; 3.4.4 Exchange Catalyzed by Iridium Cyclopentadienides; 3.5 Homogeneous Catalysis with Tritium Gas; 3.5.1 Iridium Phosphines

3.5.2 Iridium Dionate Complexes3.5.3 Iridium Cyclopentadienide Complexes; 3.6 Solvent-Free Catalytic Exchange; 3.6.1 High-Temperature Solid-State Catalytic Isotope Exchange; 3.6.2 Thermal Tritium Atom Bombardment; 3.6.3 Other Radiation-Induced Labeling Methods; References; 4 Preparation of Tritium-Labeled Compounds by Chemical Synthesis; 4.1 Catalytic Tritiations; 4.1.1 Tritiation of Carbon-Carbon Multiple Bonds; 4.1.2 Tritiation of Carbon-Heteroatom Multiple Bonds; 4.1.3 Homogeneously Catalyzed Reactions; 4.2 Catalytic Tritiolyses; 4.2.1 Tritiodehalogenations

4.2.2 Tritiolyses of Benzylic N- and O-Functions4.2.3 Tritiodesulfurizations; 4.3 Tritide Reductions; 4.3.1 Sodium Borotritide (NaB3H4 ); 4.3.2 Sodium Cyanoborotritide (NaB3H3CN); 4.3.3 Sodium/Tetramethylammonium Triacetoxyborotritide [Na/NMe4B3H(OAc)3]; 4.3.4 Lithium Tritide (Li3H); 4.3.5 Lithium Borotritide (LiB3H4); 4.3.6 Lithium Triethylborotritide (LiEt3B3H, Li-Super-Tritide); 4.3.7 Lithium Tri-sec-Butylborotritide [Li(sec-Bu3)B3H, Li T-Selectride]; 4.3.8 Lithium [3H2]Boratabicyclo[3.3.1]nonane; 4.3.9 Tritiated Borane (THF-Complex) (B2 3H6;  B3H3 .THF); 4.3.10 Tritiated Alkylboranes

4.3.11 Lithium Aluminum Tritide (LiAl3H4)

Compounds labeled with carbon-14 and tritium are indispensable tools for research in biomedical sciences, discovery and development of pharmaceuticals and agrochemicals. Preparation of Compounds Labeled with Tritium and Carbon-14 is a comprehensive, authoritative and up-to-date discussion of the strategies, synthetic approaches, reactions techniques, and resources for the preparation of compounds labeled with either of these isotopes. A large number of examples are presented for the use of isotopic sources and building blocks in the preparation of labeled target compounds, illustratin