Books: 'Small Organic Molecules'

1

Sitter, Helmut, Claudia Draxl, and Michael Ramsey, eds. Small Organic Molecules on Surfaces. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-33848-9.

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2

Mori, Tadashi, ed. Circularly Polarized Luminescence of Isolated Small Organic Molecules. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-2309-0.

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3

Sitter, Helmut. Small Organic Molecules on Surfaces: Fundamentals and Applications. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013.

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4

From small organic molecules to large: A century of progress. Washington, DC: American Chemical Society, 1993.

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5

Laganà, Antonio. Supercomputer Algorithms for Reactivity, Dynamics and Kinetics of Small Molecules. Dordrecht: Springer Netherlands, 1989.

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6

Woollins, J. Derek. Selenium and Tellurium Chemistry: From Small Molecules to Biomolecules and Materials. Berlin, Heidelberg: Springer-Verlag Berlin Heidelberg, 2011.

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7

Martin, Jonathan Paul. The synthesis and evaluation of calixarene hydrophobic hosts designed to recognise small organic molecules. Birmingham: University of Birmingham, 1991.

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8

Julius, Rebek. Hydrogen-bonded capsules: Molecular behavior in small spaces. Hackensack, NJ: World Scientific, 2015.

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9

M, Villalgordo José, ed. Solid-supported combinatorial and parallel synthesis of small-molecular-weight compound libraries. [New York]: Pergamon, 1998.

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10

Ramsey, Michael, Helmut Sitter, and Claudia Draxl. Small Organic Molecules on Surfaces: Fundamentals and Applications. Springer, 2013.

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11

Ambrosch-Draxl, Claudia, Ramsey Michael, Helmut Sitter, and Claudia Draxl. Small Organic Molecules on Surfaces: Fundamentals and Applications. Springer Berlin / Heidelberg, 2016.

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12

Mori, Tadashi. Circularly Polarized Luminescence of Isolated Small Organic Molecules. Springer, 2020.

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13

Small Organic Molecules On Surfaces Fundamentals And Applications. Springer-Verlag Berlin and Heidelberg GmbH &, 2013.

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14

Mori, Tadashi. Circularly Polarized Luminescence of Isolated Small Organic Molecules. Springer Singapore Pte. Limited, 2021.

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15

Alcácer, Luís. Electronic Structure of Organic Semiconductors: Polymers and Small Molecules. Morgan & Claypool Publishers, 2018.

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16

Alcácer, Luís. Electronic Structure of Organic Semiconductors: Polymers and Small Molecules. Morgan & Claypool Publishers, 2018.

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17

Alcácer, Luís. Electronic Structure of Organic Semiconductors: Polymers and Small Molecules. Morgan & Claypool Publishers, 2018.

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18

Laganà, Antonio. Supercomputer Algorithms for Reactivity, Dynamics and Kinetics of Small Molecules. Springer, 2011.

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19

Tavassoli, Ali. Inhibitors of Protein-Protein Interactions: Small Molecules, Cyclic Peptides, Macrocycles and Antibodies. Royal Society of Chemistry, The, 2020.

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20

Tavassoli, Ali. Inhibitors of Protein-Protein Interactions: Small Molecules, Cyclic Peptides, Macrocycles and Antibodies. Royal Society of Chemistry, The, 2020.

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21

Woollins, J. Derek, and Risto Laitinen. Selenium and Tellurium Chemistry: From Small Molecules to Biomolecules and Materials. Springer Berlin / Heidelberg, 2014.

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22

McAfee, Lyle Vernon. Cocondensation products of molybdenum trioxide with water, carbon disulfide, and various small organic molecules. 1985.

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23

Photovoltaic Technologies, Devices and Systems Based on Inorganic Materials, Small Organic Molecules and Hybrids: Volume 1493. Materials Research Society, 2013.

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24

Mark, Herman. Herman Mark: From Small Organic Molecules to Large: A Century of Progress (Profiles, Pathways, and Dreams). An American Chemical Society Publication, 1998.

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25

chemist. NoteBook Organic Chemistry Reaction Mechanism: Notebook for Organic Chemistry, Bioorganic and Biochemistry / Drawing Organic Molecules, Structures and Mechanisms / Small Hexagonal Graph Paper / 100 Pages / 8,5x11 Inches. Independently Published, 2020.

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26

chemist. NoteBook Organic Chemistry Reaction Mechanism: Notebook for Organic Chemistry, Bioorganic and Biochemistry / Drawing Organic Molecules, Structures and Mechanisms / Small Hexagonal Graph Paper / 100 Pages / 8,5x11 Inches. Independently Published, 2020.

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27

chemist. NoteBook Organic Chemistry Reaction Mechanism: Notebook for Organic Chemistry, Bioorganic and Biochemistry / Drawing Organic Molecules, Structures and Mechanisms / Small Hexagonal Graph Paper / 100 Pages / 8,5x11 Inches. Independently Published, 2020.

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28

Chemist. NoteboOK Organic Chemistry: Small HEXAGONAL Graph/ 150 Pages / 8,5x11 Inches / Notebook for Organic Chemistry, Bioorganic and Biochemistry / Representing Structures of Organic Molecules, Reactions and Mechanisms / Chemical Structure Drawing. Independently Published, 2020.

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29

Luo, Tuoping. Organic Synthesis Towards Small-Molecule Probe Development. 2011.

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30

Zhan, Chuanlang, and Donghong Yu, eds. Small-Molecule Semiconductors for High-Efficiency Organic Solar Cells. Frontiers Media SA, 2019. http://dx.doi.org/10.3389/978-2-88945-980-3.

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31

Jr, Rebek Julius. Hydrogen-Bonded Capsules: Molecular Behavior in Small Spaces. World Scientific Publishing Co Pte Ltd, 2015.

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32

Obrecht, D., and J. M. Villalgordo. Solid-Supported Combinatorial and Parallel Synthesis of Small-Molecular-Weight Compound Libraries. Elsevier Science & Technology Books, 1998.

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33

Obrecht, D., and J. M. Villalgordo. Solid-Supported Combinatorial and Parallel Synthesis of Small-Molecular-Weight Compound Libraries. Elsevier Science & Technology Books, 1998.

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34

Kirchman, David L. Degradation of organic matter. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198789406.003.0007.

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The aerobic oxidation of organic material by microbes is the focus of this chapter. Microbes account for about 50% of primary production in the biosphere, but they probably account for more than 50% of organic material oxidization and respiration (oxygen use). The traditional role of microbes is to degrade organic material and to release plant nutrients such as phosphate and ammonium as well as carbon dioxide. Microbes are responsible for more than half of soil respiration, while size fractionation experiments show that bacteria are also responsible for about half of respiration in aquatic habitats. In soils, both fungi and bacteria are important, with relative abundances and activity varying with soil type. In contrast, fungi are not common in the oceans and lakes, where they are out-competed by bacteria with their small cell size. Dead organic material, detritus, used by microbes, comes from dead plants and waste products from herbivores. It and associated microbes can be eaten by many eukaryotic organisms, forming a detritus food web. These large organisms also break up detritus into small pieces, creating more surface area on which microbes can act. Microbes in turn need to use extracellular enzymes to hydrolyze large molecular weight compounds, which releases small compounds that can be transported into cells. Fungi and bacteria use a different mechanism, “oxidative decomposition,” to degrade lignin. Organic compounds that are otherwise easily degraded (“labile”) may resist decomposition if absorbed to surfaces or surrounded by refractory organic material. Addition of labile compounds can stimulate or “prime” the degradation of other organic material. Microbes also produce organic compounds, some eventually resisting degradation for thousands of years, and contributing substantially to soil organic material in terrestrial environments and dissolved organic material in aquatic ones. The relationship between community diversity and a biochemical process depends on the metabolic redundancy among members of the microbial community. This redundancy may provide “ecological insurance” and ensure the continuation of key biogeochemical processes when environmental conditions change.

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35

James, Darius Armstrong, Anand Shah, and Anna Reed. Fungal infections in solid organ transplantation. Edited by Christopher C. Kibbler, Richard Barton, Neil A. R. Gow, Susan Howell, Donna M. MacCallum, and Rohini J. Manuel. Oxford University Press, 2017. http://dx.doi.org/10.1093/med/9780198755388.003.0034.

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Fungal infections are a significant and life-threatening complication of organ transplantation, on a global scale. Risk varies according to transplant type, with liver, lung, and small bowel transplant recipients being at particular risk. Whilst invasive candidiasis is the most common fungal infection in organ transplantation overall, aspergillosis is a particular problem in lung transplantation. In addition, a wide spectrum of fungi may cause invasive disease in organ transplantation, consequently diagnosis and treatment can be challenging. Key challenges are to understand individual risk for infection, appropriate prophylactic strategies, and molecular diagnostic approaches. Treatment options are complicated by drug–drug interactions with transplant therapy, as well as intrinsic allograft dysfunction seen in many patients. In this chapter, we review the epidemiology, risk factors, diagnosis, and management of fungal infections in solid organ transplantation.

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36

Barros, Rodrigo José Saraiva de, Tereza Cristina de Brito Azevedo, Carla de Castro Sant’Anna, Marianne Rodrigues Fernandes, Leticia Martins Lamarão, and Rommel Mario Rodríguez Burbano. Grupos sanguíneos e anticorpos anti-eritrocitários de importância transfusional. Brazil Publishing, 2020. http://dx.doi.org/10.31012/978-65-5861-112-7.

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Immunohematology is an area dedicated to the study of the interactions of the immune system and blood cells in transfusion practice. Blood transfusion is a therapeutic technique that has been widely used since the 17th century. The transfusion medicine aims to repair the pathological needs of blood components in the living organism, be it red blood cells, plasma, platelets, clotting factors, among others. Despite being a therapeutic means, transfusion of blood components can be considered at risk because it is a biological material and due to the transfusion immunological reactions that can be caused during or after the moment of transfusion. In the surface structure of red blood cells, numerous molecules of a protein, glycoprotein or glycolipid nature are found, which are also called membrane antigens that make up structures and perform transport functions, as receptors, as adhesion, enzymatic and / or complement regulatory molecules. The formation of these antigens occurs by an approximate amount of 39 genes involved in their production, of which 282 different antigens are organized in more than 30 blood group systems. This antigenic diversity is a major cause of the formation of irregular anti-erythrocyte antibodies. Therefore, with the increase in blood transfusions in surgeries, transplants and clinical treatment of cancer and other chronic diseases, a significant increase in the occurrence of alloimmunizations in polytransfused patients began to be observed. Such biological phenomena motivated us to carry out this study and the antigenic diversity motivated us to elaborate this small compendium where we also describe the main blood groups.

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37

Boterberg, Tom, Karin Dieckmann, and Mark Gaze, eds. Radiotherapy and the Cancers of Children, Teenagers, and Young Adults. Oxford University Press, 2020. http://dx.doi.org/10.1093/med/9780198793076.001.0001.

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As most cancers occur in middle-aged or older adults, only a very small proportion of the overall radiotherapy workload relates to children and young people. As there is a wide spectrum of different cancer types in this age group, not only is paediatric cancer uncommon overall but each individual type is very rare. There are many ways in which to deliver radiotherapy, including advanced photon techniques, proton beam therapy, brachytherapy, and molecular radiotherapy. For these reasons, the care of children and young people requiring radiotherapy is limited to a small number of highly specialist centres. Delivery of high-quality paediatric radiotherapy requires a multiprofessional team including radiation or clinical oncologists, therapy radiographers, physicists, dosimetrists, anaesthetists, and play specialists. This team has to interact very closely with the wider paediatric and adolescent oncology multidisciplinary team, which includes oncologists, surgeons with different anatomical expertise, radiologists, and pathologists. Children, with their developing tissues and organs, are more susceptible to long-term radiation-induced complications, including second cancers, than adults. The art of paediatric radiotherapy, therefore, is to select treatment approaches which offer the maximum chance of cure while minimizing the risk of adverse effects. Careful teamwork, peer review of radiotherapy planning, and quality assurance within a clinical trial framework offer the best chances of achieving this balance. This book covers all these aspects, highlighting the need for highly specialist teams with the extensive knowledge and the broad skillset required to offer children and young people the best possible treatments.

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38

Kirchman, David L. The physical-chemical environment of microbes. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198789406.003.0003.

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Many physical-chemical properties affecting microbes are familiar to ecologists examining large organisms in our visible world. This chapter starts by reviewing the basics of these properties, such as the importance of water for microbes in soils and temperature in all environments. Another important property, pH, has direct effects on organisms and indirect effects via how hydrogen ions determine the chemical form of key molecules and compounds in nature. Oxygen content is also critical, as it is essential to the survival of all but a few eukaryotes. Light is used as an energy source by phototrophs, but it can have deleterious effects on microbes. In addition to these familiar factors, the small size of microbes sets limits on their physical world. Microbes are said to live in a “low Reynolds number environment”. When the Reynolds number is smaller than about one, viscous forces dominate over inertial forces. For a macroscopic organism like us, moving in a low Reynolds number environment would seem like swimming in molasses. Microbes in both aquatic and terrestrial habitats live in a low Reynolds number world, one of many similarities between the two environments at the microbial scale. Most notably, even soil microbes live in an aqueous world, albeit a thin film of water on soil particles. But the soil environment is much more heterogeneous than water, with profound consequences for biogeochemical processes and interactions among microbes. The chapter ends with a discussion of how the physical-chemical environment of microbes in biofilms is quite different from that of free-living organisms.

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Books on the topic 'Small Organic Molecules'

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