Verfügbarkeit: Plenty of room for biology at the bottom :

Plenty of room for biology at the bottom :: an introduction to bionanotechnology /

This expanded and updated edition of the 2007 version introduces readers from various backgrounds to the rapidly growing interface between biology and nanotechnology. It intellectually integrates concepts, applications, and outlooks from these major scientific fields and presents them to readers fro...

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1. Verfasser:	Gazit, Ehud
Weitere Verfasser:	Mitraki, Anna
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	London : Hackensack, NJ : Imperial College Press ; Distributed by World Scientific Publishing Co. Pte. Ltd., [2013]
Ausgabe:	Second edition.
Schlagworte:	Biotechnology. Biomimetic materials. Biomolecules. Nanotechnology. Biomimetics. Bioengineering. Nanomedicine. Biotechnology Nanotechnology Nanomedicine Nanostructures Biomimetics Biotechnologie. Matériaux biomimétiques. Biomolécules. Chimie biomimétique. Nanotechnologie. Nanomédecine. bioengineering. HEALTH & FITNESS > Holism. HEALTH & FITNESS > Reference. MEDICAL > Alternative Medicine. MEDICAL > Atlases. MEDICAL > Essays. MEDICAL > Family & General Practice. MEDICAL > Holistic Medicine. MEDICAL > Osteopathy. Bioengineering Biomimetic materials Biomolecules
Online-Zugang:	Volltext
Zusammenfassung:	This expanded and updated edition of the 2007 version introduces readers from various backgrounds to the rapidly growing interface between biology and nanotechnology. It intellectually integrates concepts, applications, and outlooks from these major scientific fields and presents them to readers from diverse backgrounds in a comprehensive and didactic manner. Written by two leading nanobiologists actively involved at the forefront of the field both as researchers and educators, this book takes the reader from the fundamentals of nanobiology to the most advanced applications. The book fulfils a unique niche: to address not only students, but also scientists who are eager (and nowadays obliged) to learn about other state-of-the-art disciplines. The book is written in such a way as to be accessible to biologists, chemists, and physicists with no background in nanotechnology (for example biologists who are interested in inorganic nanostructures or physicists who would like to learn about biological assemblies and applications thereof). It is reader-friendly and will appeal to a wide audience not only in academia but also in the industry and anyone interested in learning more about nanobiotechnology.
Beschreibung:	1 online resource (xvi, 197 pages)
Bibliographie:	Includes bibliographical references and index.
ISBN:	9781848169319 1848169310 1299833381 9781299833388

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100	1		\|a Gazit, Ehud.
245	1	0	\|a Plenty of room for biology at the bottom : \|b an introduction to bionanotechnology / \|c Enud Gazit, Tel Aviv University, Israel & Anna Mitraki, University of Crete and Institute for Electronic Structure and Laser, Greece.
250			\|a Second edition.
264		1	\|a London : \|b Imperial College Press ; \|a Hackensack, NJ : \|b Distributed by World Scientific Publishing Co. Pte. Ltd., \|c [2013]
300			\|a 1 online resource (xvi, 197 pages)
336			\|a text \|b txt \|2 rdacontent
337			\|a computer \|b c \|2 rdamedia
338			\|a online resource \|b cr \|2 rdacarrier
504			\|a Includes bibliographical references and index.
588	0		\|a Print version record.
505	0		\|a Ch. 1. Introduction: nanobiotechnology and bionanotechnology. 1.1. Classical biotechnology: industrial production using biological systems. 1.2. Modern biotechnology: from industrial processes to novel therapeutics. 1.3. Modern biotechnology: immunological, enzymatic, and nucleic acid-based technology. 1.4. The interface between nanotechnology and biotechnology: bionanotechnology. 1.5. Supramolecular (bio)chemistry: the theoretical basis for self-assembly. 1.6. The next steps for self-association at the nano-scale. 1.7. Biology in nanotechnology and nano-sciences in biotechnology. 1.8. The combination of bionanotechnology and nanobiotechnology. 1.9. Nanobionics and bio-inspired nanotechnology -- ch. 2. A brief introduction to nanotechnology. 2.1. The emergence of nanotechnology: "there's plenty of room at the bottom". 2.2. Coining the term "nanotechnology" and the emergence of the nanotechnology concept. 2.3. Manipulating molecules: the scanning probe microscopes. 2.4. Carbon fullerene: a new form of carbon. 2.5. Carbon nanotubes: key building blocks for future nanotechnological applications. 2.6. A single layer of carbon: graphene. 2.7. Non-carbon nanotubes and fullerene-like material: the inorganic nanomaterials. 2.8. Quantum dots and other nanoparticles. 2.9. Nanowires, nanorods, and other nanomaterials. 2.10. Magnetic nanoparticles -- ch. 3. Natural biological assembly at the nanometric scale. 3.1. The process of self-assembly and self-organization in biology. 3.2. Organization of bacterial S-layers. 3.3. Self-organization of viruses. 3.4. Self-organization of phospholipid membranes. 3.5. Fibrillar cytoskeleton assemblies. 3.6. Nucleic acids: the genetic information media and a template for nanotechnological applications. 3.7. Oligosaccharides and polysaccharides: another class of biological polymers. 3.8. Amyloid fibrils as self-assembled nano-scale bio-assemblies. 3.9. Silk: natural fibrillar supramolecular protein assembly. 3.10. Ribosome: the protein assembly line instrument. 3.11. Other complex machines in the genetic code expression. 3.12. Protein quality-control machinery: the proteasome. 3.13. Biological nano-motors: kinesin and dynein. 3.14. Other nano-motors: flagella and cilia. 3.15. Ion channels: nano-pores of high specificity -- ch. 4. Nanometric biological assemblies: molecular and chemical basis for interaction. 4.1. Emergence of biological activity through self-assembly. 4.2. Molecular recognition and chemical affinity. 4.3. Affinity and specificity of biological interactions. 4.4. The relation between thermodynamics and kinetics of dissociation. 4.5. The chemical basis for molecular recognition and specific binding. 4.6. The formation of specific complexes by an increase in entropy.
505	8		\|a Ch. 5. Molecular recognition and the assembly of biological structures. 5.1. Antibodies as the molecular sensors of recognition. 5.2. Selection of antibodies and equivalent systems in the test tube. 5.3. Recognition between nucleic acids by proteins. 5.4. Interaction between receptors and ligands. 5.5. Molecular recognition between nucleic acids. 5.6. Aptamers -- ch. 6. Self-assembly of biological and bio-inspired nanomaterials. 6.1. Formation of DNA-based materials. 6.2. Assembly of peptide-based nanomaterials. 6.3. The first peptide nanotubes. 6.4. Amphiphile and surfactant-like peptide building blocks. 6.5. Charge complementary as a driving force for self-assembly. 6.6. Conjugation of peptides for self-assembly. 6.7. Aromatic interactions for the formation of nano-structures. 6.8. The formation of aromatic dipeptide nanotubes (ADNT). 6.9. The formation of spherical nano-structures by short peptides. 6.10. Helical peptide building blocks. 6.11. Peptide nucleic acid (PNA) -- ch. 7. Application of biological assemblies in nanotechnology. 7.1. The use of S-layers for nanolithography. 7.2. The use of DNA for fabrication of conductive nanowires. 7.3. Amyloid fibrils as templates for nanowire fabrication. 7.4. Metallization of actin filaments by chemical modification. 7.5. The use of aromatic peptide nanotubes. 7.6. Bacteriophages as novel biomaterials. 7.7. The use of peptide templates for biomineralization. 7.8. Production of inorganic composite nanomaterials. 7.9. The utilization of biomineralization in nanotechnology -- ch. 8. Medical and other applications of bionanotechnology. 8.1. The use of drug nanocrystals for improved application. 8.2. The use of nano-containers for drug delivery. 8.3. The use of inorganic nanowires for biological detection. 8.4. The use of soft lithography for biotechnology. 8.5. Contrast agents by nanomagnetic materials. 8.6. Nanoagriculture. 8.7. Water technology and nanotechnology. 8.8. Nanocosmetics. 8.9. Solar energy applications -- ch. 9. Future prospects for nanobiotechnology and bionanotechnology. 9.1. The marriage of molecular biology and nanotechnology. 9.2. The engineering of modified biological systems for the assembly of nano-structures. 9.3. Nanotechnology and tissue engineering. 9.4. Engineering of the brain tissue. 9.5. Making artificial biological inorganic composites. 9.6. Nanobio machines and nano-robots -- ch. 10. Concluding remarks: the prospects and dangers of the nanobiological revolution.
520			\|a This expanded and updated edition of the 2007 version introduces readers from various backgrounds to the rapidly growing interface between biology and nanotechnology. It intellectually integrates concepts, applications, and outlooks from these major scientific fields and presents them to readers from diverse backgrounds in a comprehensive and didactic manner. Written by two leading nanobiologists actively involved at the forefront of the field both as researchers and educators, this book takes the reader from the fundamentals of nanobiology to the most advanced applications. The book fulfils a unique niche: to address not only students, but also scientists who are eager (and nowadays obliged) to learn about other state-of-the-art disciplines. The book is written in such a way as to be accessible to biologists, chemists, and physicists with no background in nanotechnology (for example biologists who are interested in inorganic nanostructures or physicists who would like to learn about biological assemblies and applications thereof). It is reader-friendly and will appeal to a wide audience not only in academia but also in the industry and anyone interested in learning more about nanobiotechnology.
650		0	\|a Biotechnology. \|0 http://id.loc.gov/authorities/subjects/sh85014263
650		0	\|a Biomimetic materials. \|0 http://id.loc.gov/authorities/subjects/sh2009009164
650		0	\|a Biomolecules. \|0 http://id.loc.gov/authorities/subjects/sh85014249
650		0	\|a Nanotechnology. \|0 http://id.loc.gov/authorities/subjects/sh91001490
650		0	\|a Biomimetics. \|0 http://id.loc.gov/authorities/subjects/sh89000711
650		0	\|a Bioengineering. \|0 http://id.loc.gov/authorities/subjects/sh85014134
650		0	\|a Nanomedicine. \|0 http://id.loc.gov/authorities/subjects/sh2007008651
650	1	2	\|a Biotechnology \|0 https://id.nlm.nih.gov/mesh/D001709
650	1	2	\|a Nanotechnology \|0 https://id.nlm.nih.gov/mesh/D036103
650	2	2	\|a Nanomedicine
650	2	2	\|a Nanostructures \|0 https://id.nlm.nih.gov/mesh/D049329
650		2	\|a Biomimetics \|0 https://id.nlm.nih.gov/mesh/D032701
650		6	\|a Biotechnologie.
650		6	\|a Matériaux biomimétiques.
650		6	\|a Biomolécules.
650		6	\|a Chimie biomimétique.
650		6	\|a Nanotechnologie.
650		6	\|a Nanomédecine.
650		7	\|a bioengineering. \|2 aat
650		7	\|a HEALTH & FITNESS \|x Holism. \|2 bisacsh
650		7	\|a HEALTH & FITNESS \|x Reference. \|2 bisacsh
650		7	\|a MEDICAL \|x Alternative Medicine. \|2 bisacsh
650		7	\|a MEDICAL \|x Atlases. \|2 bisacsh
650		7	\|a MEDICAL \|x Essays. \|2 bisacsh
650		7	\|a MEDICAL \|x Family & General Practice. \|2 bisacsh
650		7	\|a MEDICAL \|x Holistic Medicine. \|2 bisacsh
650		7	\|a MEDICAL \|x Osteopathy. \|2 bisacsh
650		7	\|a Bioengineering \|2 fast
650		7	\|a Biomimetic materials \|2 fast
650		7	\|a Biomimetics \|2 fast
650		7	\|a Biomolecules \|2 fast
650		7	\|a Biotechnology \|2 fast
650		7	\|a Nanotechnology \|2 fast
700	1		\|a Mitraki, Anna.
758			\|i has work: \|a Plenty of room for biology at the bottom (Text) \|1 https://id.oclc.org/worldcat/entity/E39PCGyJ37mDFbxjtCyvWx4J8P \|4 https://id.oclc.org/worldcat/ontology/hasWork
776	0	8	\|i Print version: \|a Gazit, Ehud. \|t Plenty of room for biology at the bottom. \|b Second edition \|z 9781848169302 \|w (DLC) 2012048470 \|w (OCoLC)836257751
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contents	Ch. 1. Introduction: nanobiotechnology and bionanotechnology. 1.1. Classical biotechnology: industrial production using biological systems. 1.2. Modern biotechnology: from industrial processes to novel therapeutics. 1.3. Modern biotechnology: immunological, enzymatic, and nucleic acid-based technology. 1.4. The interface between nanotechnology and biotechnology: bionanotechnology. 1.5. Supramolecular (bio)chemistry: the theoretical basis for self-assembly. 1.6. The next steps for self-association at the nano-scale. 1.7. Biology in nanotechnology and nano-sciences in biotechnology. 1.8. The combination of bionanotechnology and nanobiotechnology. 1.9. Nanobionics and bio-inspired nanotechnology -- ch. 2. A brief introduction to nanotechnology. 2.1. The emergence of nanotechnology: "there's plenty of room at the bottom". 2.2. Coining the term "nanotechnology" and the emergence of the nanotechnology concept. 2.3. Manipulating molecules: the scanning probe microscopes. 2.4. Carbon fullerene: a new form of carbon. 2.5. Carbon nanotubes: key building blocks for future nanotechnological applications. 2.6. A single layer of carbon: graphene. 2.7. Non-carbon nanotubes and fullerene-like material: the inorganic nanomaterials. 2.8. Quantum dots and other nanoparticles. 2.9. Nanowires, nanorods, and other nanomaterials. 2.10. Magnetic nanoparticles -- ch. 3. Natural biological assembly at the nanometric scale. 3.1. The process of self-assembly and self-organization in biology. 3.2. Organization of bacterial S-layers. 3.3. Self-organization of viruses. 3.4. Self-organization of phospholipid membranes. 3.5. Fibrillar cytoskeleton assemblies. 3.6. Nucleic acids: the genetic information media and a template for nanotechnological applications. 3.7. Oligosaccharides and polysaccharides: another class of biological polymers. 3.8. Amyloid fibrils as self-assembled nano-scale bio-assemblies. 3.9. Silk: natural fibrillar supramolecular protein assembly. 3.10. Ribosome: the protein assembly line instrument. 3.11. Other complex machines in the genetic code expression. 3.12. Protein quality-control machinery: the proteasome. 3.13. Biological nano-motors: kinesin and dynein. 3.14. Other nano-motors: flagella and cilia. 3.15. Ion channels: nano-pores of high specificity -- ch. 4. Nanometric biological assemblies: molecular and chemical basis for interaction. 4.1. Emergence of biological activity through self-assembly. 4.2. Molecular recognition and chemical affinity. 4.3. Affinity and specificity of biological interactions. 4.4. The relation between thermodynamics and kinetics of dissociation. 4.5. The chemical basis for molecular recognition and specific binding. 4.6. The formation of specific complexes by an increase in entropy. Ch. 5. Molecular recognition and the assembly of biological structures. 5.1. Antibodies as the molecular sensors of recognition. 5.2. Selection of antibodies and equivalent systems in the test tube. 5.3. Recognition between nucleic acids by proteins. 5.4. Interaction between receptors and ligands. 5.5. Molecular recognition between nucleic acids. 5.6. Aptamers -- ch. 6. Self-assembly of biological and bio-inspired nanomaterials. 6.1. Formation of DNA-based materials. 6.2. Assembly of peptide-based nanomaterials. 6.3. The first peptide nanotubes. 6.4. Amphiphile and surfactant-like peptide building blocks. 6.5. Charge complementary as a driving force for self-assembly. 6.6. Conjugation of peptides for self-assembly. 6.7. Aromatic interactions for the formation of nano-structures. 6.8. The formation of aromatic dipeptide nanotubes (ADNT). 6.9. The formation of spherical nano-structures by short peptides. 6.10. Helical peptide building blocks. 6.11. Peptide nucleic acid (PNA) -- ch. 7. Application of biological assemblies in nanotechnology. 7.1. The use of S-layers for nanolithography. 7.2. The use of DNA for fabrication of conductive nanowires. 7.3. Amyloid fibrils as templates for nanowire fabrication. 7.4. Metallization of actin filaments by chemical modification. 7.5. The use of aromatic peptide nanotubes. 7.6. Bacteriophages as novel biomaterials. 7.7. The use of peptide templates for biomineralization. 7.8. Production of inorganic composite nanomaterials. 7.9. The utilization of biomineralization in nanotechnology -- ch. 8. Medical and other applications of bionanotechnology. 8.1. The use of drug nanocrystals for improved application. 8.2. The use of nano-containers for drug delivery. 8.3. The use of inorganic nanowires for biological detection. 8.4. The use of soft lithography for biotechnology. 8.5. Contrast agents by nanomagnetic materials. 8.6. Nanoagriculture. 8.7. Water technology and nanotechnology. 8.8. Nanocosmetics. 8.9. Solar energy applications -- ch. 9. Future prospects for nanobiotechnology and bionanotechnology. 9.1. The marriage of molecular biology and nanotechnology. 9.2. The engineering of modified biological systems for the assembly of nano-structures. 9.3. Nanotechnology and tissue engineering. 9.4. Engineering of the brain tissue. 9.5. Making artificial biological inorganic composites. 9.6. Nanobio machines and nano-robots -- ch. 10. Concluding remarks: the prospects and dangers of the nanobiological revolution.
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Pte. Ltd.,</subfield><subfield code="c">[2013]</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 online resource (xvi, 197 pages)</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="a">text</subfield><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="a">computer</subfield><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="a">online resource</subfield><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="504" ind1=" " ind2=" "><subfield code="a">Includes bibliographical references and index.</subfield></datafield><datafield tag="588" ind1="0" ind2=" "><subfield code="a">Print version record.</subfield></datafield><datafield tag="505" ind1="0" ind2=" "><subfield code="a">Ch. 1. Introduction: nanobiotechnology and bionanotechnology. 1.1. Classical biotechnology: industrial production using biological systems. 1.2. Modern biotechnology: from industrial processes to novel therapeutics. 1.3. Modern biotechnology: immunological, enzymatic, and nucleic acid-based technology. 1.4. The interface between nanotechnology and biotechnology: bionanotechnology. 1.5. Supramolecular (bio)chemistry: the theoretical basis for self-assembly. 1.6. The next steps for self-association at the nano-scale. 1.7. Biology in nanotechnology and nano-sciences in biotechnology. 1.8. The combination of bionanotechnology and nanobiotechnology. 1.9. Nanobionics and bio-inspired nanotechnology -- ch. 2. A brief introduction to nanotechnology. 2.1. The emergence of nanotechnology: "there's plenty of room at the bottom". 2.2. Coining the term "nanotechnology" and the emergence of the nanotechnology concept. 2.3. Manipulating molecules: the scanning probe microscopes. 2.4. Carbon fullerene: a new form of carbon. 2.5. Carbon nanotubes: key building blocks for future nanotechnological applications. 2.6. A single layer of carbon: graphene. 2.7. Non-carbon nanotubes and fullerene-like material: the inorganic nanomaterials. 2.8. Quantum dots and other nanoparticles. 2.9. Nanowires, nanorods, and other nanomaterials. 2.10. Magnetic nanoparticles -- ch. 3. Natural biological assembly at the nanometric scale. 3.1. The process of self-assembly and self-organization in biology. 3.2. Organization of bacterial S-layers. 3.3. Self-organization of viruses. 3.4. Self-organization of phospholipid membranes. 3.5. Fibrillar cytoskeleton assemblies. 3.6. Nucleic acids: the genetic information media and a template for nanotechnological applications. 3.7. Oligosaccharides and polysaccharides: another class of biological polymers. 3.8. Amyloid fibrils as self-assembled nano-scale bio-assemblies. 3.9. Silk: natural fibrillar supramolecular protein assembly. 3.10. Ribosome: the protein assembly line instrument. 3.11. Other complex machines in the genetic code expression. 3.12. Protein quality-control machinery: the proteasome. 3.13. Biological nano-motors: kinesin and dynein. 3.14. Other nano-motors: flagella and cilia. 3.15. Ion channels: nano-pores of high specificity -- ch. 4. Nanometric biological assemblies: molecular and chemical basis for interaction. 4.1. Emergence of biological activity through self-assembly. 4.2. Molecular recognition and chemical affinity. 4.3. Affinity and specificity of biological interactions. 4.4. The relation between thermodynamics and kinetics of dissociation. 4.5. The chemical basis for molecular recognition and specific binding. 4.6. The formation of specific complexes by an increase in entropy.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Ch. 5. Molecular recognition and the assembly of biological structures. 5.1. Antibodies as the molecular sensors of recognition. 5.2. Selection of antibodies and equivalent systems in the test tube. 5.3. Recognition between nucleic acids by proteins. 5.4. Interaction between receptors and ligands. 5.5. Molecular recognition between nucleic acids. 5.6. Aptamers -- ch. 6. Self-assembly of biological and bio-inspired nanomaterials. 6.1. Formation of DNA-based materials. 6.2. Assembly of peptide-based nanomaterials. 6.3. The first peptide nanotubes. 6.4. Amphiphile and surfactant-like peptide building blocks. 6.5. Charge complementary as a driving force for self-assembly. 6.6. Conjugation of peptides for self-assembly. 6.7. Aromatic interactions for the formation of nano-structures. 6.8. The formation of aromatic dipeptide nanotubes (ADNT). 6.9. The formation of spherical nano-structures by short peptides. 6.10. Helical peptide building blocks. 6.11. Peptide nucleic acid (PNA) -- ch. 7. Application of biological assemblies in nanotechnology. 7.1. The use of S-layers for nanolithography. 7.2. The use of DNA for fabrication of conductive nanowires. 7.3. Amyloid fibrils as templates for nanowire fabrication. 7.4. Metallization of actin filaments by chemical modification. 7.5. The use of aromatic peptide nanotubes. 7.6. Bacteriophages as novel biomaterials. 7.7. The use of peptide templates for biomineralization. 7.8. Production of inorganic composite nanomaterials. 7.9. The utilization of biomineralization in nanotechnology -- ch. 8. Medical and other applications of bionanotechnology. 8.1. The use of drug nanocrystals for improved application. 8.2. The use of nano-containers for drug delivery. 8.3. The use of inorganic nanowires for biological detection. 8.4. The use of soft lithography for biotechnology. 8.5. Contrast agents by nanomagnetic materials. 8.6. Nanoagriculture. 8.7. Water technology and nanotechnology. 8.8. Nanocosmetics. 8.9. Solar energy applications -- ch. 9. Future prospects for nanobiotechnology and bionanotechnology. 9.1. The marriage of molecular biology and nanotechnology. 9.2. The engineering of modified biological systems for the assembly of nano-structures. 9.3. Nanotechnology and tissue engineering. 9.4. Engineering of the brain tissue. 9.5. Making artificial biological inorganic composites. 9.6. Nanobio machines and nano-robots -- ch. 10. Concluding remarks: the prospects and dangers of the nanobiological revolution.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">This expanded and updated edition of the 2007 version introduces readers from various backgrounds to the rapidly growing interface between biology and nanotechnology. It intellectually integrates concepts, applications, and outlooks from these major scientific fields and presents them to readers from diverse backgrounds in a comprehensive and didactic manner. Written by two leading nanobiologists actively involved at the forefront of the field both as researchers and educators, this book takes the reader from the fundamentals of nanobiology to the most advanced applications. The book fulfils a unique niche: to address not only students, but also scientists who are eager (and nowadays obliged) to learn about other state-of-the-art disciplines. The book is written in such a way as to be accessible to biologists, chemists, and physicists with no background in nanotechnology (for example biologists who are interested in inorganic nanostructures or physicists who would like to learn about biological assemblies and applications thereof). 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spelling	Gazit, Ehud. Plenty of room for biology at the bottom : an introduction to bionanotechnology / Enud Gazit, Tel Aviv University, Israel & Anna Mitraki, University of Crete and Institute for Electronic Structure and Laser, Greece. Second edition. London : Imperial College Press ; Hackensack, NJ : Distributed by World Scientific Publishing Co. Pte. Ltd., [2013] 1 online resource (xvi, 197 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier Includes bibliographical references and index. Print version record. Ch. 1. Introduction: nanobiotechnology and bionanotechnology. 1.1. Classical biotechnology: industrial production using biological systems. 1.2. Modern biotechnology: from industrial processes to novel therapeutics. 1.3. Modern biotechnology: immunological, enzymatic, and nucleic acid-based technology. 1.4. The interface between nanotechnology and biotechnology: bionanotechnology. 1.5. Supramolecular (bio)chemistry: the theoretical basis for self-assembly. 1.6. The next steps for self-association at the nano-scale. 1.7. Biology in nanotechnology and nano-sciences in biotechnology. 1.8. The combination of bionanotechnology and nanobiotechnology. 1.9. Nanobionics and bio-inspired nanotechnology -- ch. 2. A brief introduction to nanotechnology. 2.1. The emergence of nanotechnology: "there's plenty of room at the bottom". 2.2. Coining the term "nanotechnology" and the emergence of the nanotechnology concept. 2.3. Manipulating molecules: the scanning probe microscopes. 2.4. Carbon fullerene: a new form of carbon. 2.5. Carbon nanotubes: key building blocks for future nanotechnological applications. 2.6. A single layer of carbon: graphene. 2.7. Non-carbon nanotubes and fullerene-like material: the inorganic nanomaterials. 2.8. Quantum dots and other nanoparticles. 2.9. Nanowires, nanorods, and other nanomaterials. 2.10. Magnetic nanoparticles -- ch. 3. Natural biological assembly at the nanometric scale. 3.1. The process of self-assembly and self-organization in biology. 3.2. Organization of bacterial S-layers. 3.3. Self-organization of viruses. 3.4. Self-organization of phospholipid membranes. 3.5. Fibrillar cytoskeleton assemblies. 3.6. Nucleic acids: the genetic information media and a template for nanotechnological applications. 3.7. Oligosaccharides and polysaccharides: another class of biological polymers. 3.8. Amyloid fibrils as self-assembled nano-scale bio-assemblies. 3.9. Silk: natural fibrillar supramolecular protein assembly. 3.10. Ribosome: the protein assembly line instrument. 3.11. Other complex machines in the genetic code expression. 3.12. Protein quality-control machinery: the proteasome. 3.13. Biological nano-motors: kinesin and dynein. 3.14. Other nano-motors: flagella and cilia. 3.15. Ion channels: nano-pores of high specificity -- ch. 4. Nanometric biological assemblies: molecular and chemical basis for interaction. 4.1. Emergence of biological activity through self-assembly. 4.2. Molecular recognition and chemical affinity. 4.3. Affinity and specificity of biological interactions. 4.4. The relation between thermodynamics and kinetics of dissociation. 4.5. The chemical basis for molecular recognition and specific binding. 4.6. The formation of specific complexes by an increase in entropy. Ch. 5. Molecular recognition and the assembly of biological structures. 5.1. Antibodies as the molecular sensors of recognition. 5.2. Selection of antibodies and equivalent systems in the test tube. 5.3. Recognition between nucleic acids by proteins. 5.4. Interaction between receptors and ligands. 5.5. Molecular recognition between nucleic acids. 5.6. Aptamers -- ch. 6. Self-assembly of biological and bio-inspired nanomaterials. 6.1. Formation of DNA-based materials. 6.2. Assembly of peptide-based nanomaterials. 6.3. The first peptide nanotubes. 6.4. Amphiphile and surfactant-like peptide building blocks. 6.5. Charge complementary as a driving force for self-assembly. 6.6. Conjugation of peptides for self-assembly. 6.7. Aromatic interactions for the formation of nano-structures. 6.8. The formation of aromatic dipeptide nanotubes (ADNT). 6.9. The formation of spherical nano-structures by short peptides. 6.10. Helical peptide building blocks. 6.11. Peptide nucleic acid (PNA) -- ch. 7. Application of biological assemblies in nanotechnology. 7.1. The use of S-layers for nanolithography. 7.2. The use of DNA for fabrication of conductive nanowires. 7.3. Amyloid fibrils as templates for nanowire fabrication. 7.4. Metallization of actin filaments by chemical modification. 7.5. The use of aromatic peptide nanotubes. 7.6. Bacteriophages as novel biomaterials. 7.7. The use of peptide templates for biomineralization. 7.8. Production of inorganic composite nanomaterials. 7.9. The utilization of biomineralization in nanotechnology -- ch. 8. Medical and other applications of bionanotechnology. 8.1. The use of drug nanocrystals for improved application. 8.2. The use of nano-containers for drug delivery. 8.3. The use of inorganic nanowires for biological detection. 8.4. The use of soft lithography for biotechnology. 8.5. Contrast agents by nanomagnetic materials. 8.6. Nanoagriculture. 8.7. Water technology and nanotechnology. 8.8. Nanocosmetics. 8.9. Solar energy applications -- ch. 9. Future prospects for nanobiotechnology and bionanotechnology. 9.1. The marriage of molecular biology and nanotechnology. 9.2. The engineering of modified biological systems for the assembly of nano-structures. 9.3. Nanotechnology and tissue engineering. 9.4. Engineering of the brain tissue. 9.5. Making artificial biological inorganic composites. 9.6. Nanobio machines and nano-robots -- ch. 10. Concluding remarks: the prospects and dangers of the nanobiological revolution. This expanded and updated edition of the 2007 version introduces readers from various backgrounds to the rapidly growing interface between biology and nanotechnology. It intellectually integrates concepts, applications, and outlooks from these major scientific fields and presents them to readers from diverse backgrounds in a comprehensive and didactic manner. Written by two leading nanobiologists actively involved at the forefront of the field both as researchers and educators, this book takes the reader from the fundamentals of nanobiology to the most advanced applications. The book fulfils a unique niche: to address not only students, but also scientists who are eager (and nowadays obliged) to learn about other state-of-the-art disciplines. The book is written in such a way as to be accessible to biologists, chemists, and physicists with no background in nanotechnology (for example biologists who are interested in inorganic nanostructures or physicists who would like to learn about biological assemblies and applications thereof). It is reader-friendly and will appeal to a wide audience not only in academia but also in the industry and anyone interested in learning more about nanobiotechnology. Biotechnology. http://id.loc.gov/authorities/subjects/sh85014263 Biomimetic materials. http://id.loc.gov/authorities/subjects/sh2009009164 Biomolecules. http://id.loc.gov/authorities/subjects/sh85014249 Nanotechnology. http://id.loc.gov/authorities/subjects/sh91001490 Biomimetics. http://id.loc.gov/authorities/subjects/sh89000711 Bioengineering. http://id.loc.gov/authorities/subjects/sh85014134 Nanomedicine. http://id.loc.gov/authorities/subjects/sh2007008651 Biotechnology https://id.nlm.nih.gov/mesh/D001709 Nanotechnology https://id.nlm.nih.gov/mesh/D036103 Nanomedicine Nanostructures https://id.nlm.nih.gov/mesh/D049329 Biomimetics https://id.nlm.nih.gov/mesh/D032701 Biotechnologie. Matériaux biomimétiques. Biomolécules. Chimie biomimétique. Nanotechnologie. Nanomédecine. bioengineering. aat HEALTH & FITNESS Holism. bisacsh HEALTH & FITNESS Reference. bisacsh MEDICAL Alternative Medicine. bisacsh MEDICAL Atlases. bisacsh MEDICAL Essays. bisacsh MEDICAL Family & General Practice. bisacsh MEDICAL Holistic Medicine. bisacsh MEDICAL Osteopathy. bisacsh Bioengineering fast Biomimetic materials fast Biomimetics fast Biomolecules fast Biotechnology fast Nanotechnology fast Mitraki, Anna. has work: Plenty of room for biology at the bottom (Text) https://id.oclc.org/worldcat/entity/E39PCGyJ37mDFbxjtCyvWx4J8P https://id.oclc.org/worldcat/ontology/hasWork Print version: Gazit, Ehud. Plenty of room for biology at the bottom. Second edition 9781848169302 (DLC) 2012048470 (OCoLC)836257751 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=637071 Volltext
spellingShingle	Gazit, Ehud Plenty of room for biology at the bottom : an introduction to bionanotechnology / Ch. 1. Introduction: nanobiotechnology and bionanotechnology. 1.1. Classical biotechnology: industrial production using biological systems. 1.2. Modern biotechnology: from industrial processes to novel therapeutics. 1.3. Modern biotechnology: immunological, enzymatic, and nucleic acid-based technology. 1.4. The interface between nanotechnology and biotechnology: bionanotechnology. 1.5. Supramolecular (bio)chemistry: the theoretical basis for self-assembly. 1.6. The next steps for self-association at the nano-scale. 1.7. Biology in nanotechnology and nano-sciences in biotechnology. 1.8. The combination of bionanotechnology and nanobiotechnology. 1.9. Nanobionics and bio-inspired nanotechnology -- ch. 2. A brief introduction to nanotechnology. 2.1. The emergence of nanotechnology: "there's plenty of room at the bottom". 2.2. Coining the term "nanotechnology" and the emergence of the nanotechnology concept. 2.3. Manipulating molecules: the scanning probe microscopes. 2.4. Carbon fullerene: a new form of carbon. 2.5. Carbon nanotubes: key building blocks for future nanotechnological applications. 2.6. A single layer of carbon: graphene. 2.7. Non-carbon nanotubes and fullerene-like material: the inorganic nanomaterials. 2.8. Quantum dots and other nanoparticles. 2.9. Nanowires, nanorods, and other nanomaterials. 2.10. Magnetic nanoparticles -- ch. 3. Natural biological assembly at the nanometric scale. 3.1. The process of self-assembly and self-organization in biology. 3.2. Organization of bacterial S-layers. 3.3. Self-organization of viruses. 3.4. Self-organization of phospholipid membranes. 3.5. Fibrillar cytoskeleton assemblies. 3.6. Nucleic acids: the genetic information media and a template for nanotechnological applications. 3.7. Oligosaccharides and polysaccharides: another class of biological polymers. 3.8. Amyloid fibrils as self-assembled nano-scale bio-assemblies. 3.9. Silk: natural fibrillar supramolecular protein assembly. 3.10. Ribosome: the protein assembly line instrument. 3.11. Other complex machines in the genetic code expression. 3.12. Protein quality-control machinery: the proteasome. 3.13. Biological nano-motors: kinesin and dynein. 3.14. Other nano-motors: flagella and cilia. 3.15. Ion channels: nano-pores of high specificity -- ch. 4. Nanometric biological assemblies: molecular and chemical basis for interaction. 4.1. Emergence of biological activity through self-assembly. 4.2. Molecular recognition and chemical affinity. 4.3. Affinity and specificity of biological interactions. 4.4. The relation between thermodynamics and kinetics of dissociation. 4.5. The chemical basis for molecular recognition and specific binding. 4.6. The formation of specific complexes by an increase in entropy. Ch. 5. Molecular recognition and the assembly of biological structures. 5.1. Antibodies as the molecular sensors of recognition. 5.2. Selection of antibodies and equivalent systems in the test tube. 5.3. Recognition between nucleic acids by proteins. 5.4. Interaction between receptors and ligands. 5.5. Molecular recognition between nucleic acids. 5.6. Aptamers -- ch. 6. Self-assembly of biological and bio-inspired nanomaterials. 6.1. Formation of DNA-based materials. 6.2. Assembly of peptide-based nanomaterials. 6.3. The first peptide nanotubes. 6.4. Amphiphile and surfactant-like peptide building blocks. 6.5. Charge complementary as a driving force for self-assembly. 6.6. Conjugation of peptides for self-assembly. 6.7. Aromatic interactions for the formation of nano-structures. 6.8. The formation of aromatic dipeptide nanotubes (ADNT). 6.9. The formation of spherical nano-structures by short peptides. 6.10. Helical peptide building blocks. 6.11. Peptide nucleic acid (PNA) -- ch. 7. Application of biological assemblies in nanotechnology. 7.1. The use of S-layers for nanolithography. 7.2. The use of DNA for fabrication of conductive nanowires. 7.3. Amyloid fibrils as templates for nanowire fabrication. 7.4. Metallization of actin filaments by chemical modification. 7.5. The use of aromatic peptide nanotubes. 7.6. Bacteriophages as novel biomaterials. 7.7. The use of peptide templates for biomineralization. 7.8. Production of inorganic composite nanomaterials. 7.9. The utilization of biomineralization in nanotechnology -- ch. 8. Medical and other applications of bionanotechnology. 8.1. The use of drug nanocrystals for improved application. 8.2. The use of nano-containers for drug delivery. 8.3. The use of inorganic nanowires for biological detection. 8.4. The use of soft lithography for biotechnology. 8.5. Contrast agents by nanomagnetic materials. 8.6. Nanoagriculture. 8.7. Water technology and nanotechnology. 8.8. Nanocosmetics. 8.9. Solar energy applications -- ch. 9. Future prospects for nanobiotechnology and bionanotechnology. 9.1. The marriage of molecular biology and nanotechnology. 9.2. The engineering of modified biological systems for the assembly of nano-structures. 9.3. Nanotechnology and tissue engineering. 9.4. Engineering of the brain tissue. 9.5. Making artificial biological inorganic composites. 9.6. Nanobio machines and nano-robots -- ch. 10. Concluding remarks: the prospects and dangers of the nanobiological revolution. Biotechnology. http://id.loc.gov/authorities/subjects/sh85014263 Biomimetic materials. http://id.loc.gov/authorities/subjects/sh2009009164 Biomolecules. http://id.loc.gov/authorities/subjects/sh85014249 Nanotechnology. http://id.loc.gov/authorities/subjects/sh91001490 Biomimetics. http://id.loc.gov/authorities/subjects/sh89000711 Bioengineering. http://id.loc.gov/authorities/subjects/sh85014134 Nanomedicine. http://id.loc.gov/authorities/subjects/sh2007008651 Biotechnology https://id.nlm.nih.gov/mesh/D001709 Nanotechnology https://id.nlm.nih.gov/mesh/D036103 Nanomedicine Nanostructures https://id.nlm.nih.gov/mesh/D049329 Biomimetics https://id.nlm.nih.gov/mesh/D032701 Biotechnologie. Matériaux biomimétiques. Biomolécules. Chimie biomimétique. Nanotechnologie. Nanomédecine. bioengineering. aat HEALTH & FITNESS Holism. bisacsh HEALTH & FITNESS Reference. bisacsh MEDICAL Alternative Medicine. bisacsh MEDICAL Atlases. bisacsh MEDICAL Essays. bisacsh MEDICAL Family & General Practice. bisacsh MEDICAL Holistic Medicine. bisacsh MEDICAL Osteopathy. bisacsh Bioengineering fast Biomimetic materials fast Biomimetics fast Biomolecules fast Biotechnology fast Nanotechnology fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85014263 http://id.loc.gov/authorities/subjects/sh2009009164 http://id.loc.gov/authorities/subjects/sh85014249 http://id.loc.gov/authorities/subjects/sh91001490 http://id.loc.gov/authorities/subjects/sh89000711 http://id.loc.gov/authorities/subjects/sh85014134 http://id.loc.gov/authorities/subjects/sh2007008651 https://id.nlm.nih.gov/mesh/D001709 https://id.nlm.nih.gov/mesh/D036103 https://id.nlm.nih.gov/mesh/D049329 https://id.nlm.nih.gov/mesh/D032701
title	Plenty of room for biology at the bottom : an introduction to bionanotechnology /
title_auth	Plenty of room for biology at the bottom : an introduction to bionanotechnology /
title_exact_search	Plenty of room for biology at the bottom : an introduction to bionanotechnology /
title_full	Plenty of room for biology at the bottom : an introduction to bionanotechnology / Enud Gazit, Tel Aviv University, Israel & Anna Mitraki, University of Crete and Institute for Electronic Structure and Laser, Greece.
title_fullStr	Plenty of room for biology at the bottom : an introduction to bionanotechnology / Enud Gazit, Tel Aviv University, Israel & Anna Mitraki, University of Crete and Institute for Electronic Structure and Laser, Greece.
title_full_unstemmed	Plenty of room for biology at the bottom : an introduction to bionanotechnology / Enud Gazit, Tel Aviv University, Israel & Anna Mitraki, University of Crete and Institute for Electronic Structure and Laser, Greece.
title_short	Plenty of room for biology at the bottom :
title_sort	plenty of room for biology at the bottom an introduction to bionanotechnology
title_sub	an introduction to bionanotechnology /
topic	Biotechnology. http://id.loc.gov/authorities/subjects/sh85014263 Biomimetic materials. http://id.loc.gov/authorities/subjects/sh2009009164 Biomolecules. http://id.loc.gov/authorities/subjects/sh85014249 Nanotechnology. http://id.loc.gov/authorities/subjects/sh91001490 Biomimetics. http://id.loc.gov/authorities/subjects/sh89000711 Bioengineering. http://id.loc.gov/authorities/subjects/sh85014134 Nanomedicine. http://id.loc.gov/authorities/subjects/sh2007008651 Biotechnology https://id.nlm.nih.gov/mesh/D001709 Nanotechnology https://id.nlm.nih.gov/mesh/D036103 Nanomedicine Nanostructures https://id.nlm.nih.gov/mesh/D049329 Biomimetics https://id.nlm.nih.gov/mesh/D032701 Biotechnologie. Matériaux biomimétiques. Biomolécules. Chimie biomimétique. Nanotechnologie. Nanomédecine. bioengineering. aat HEALTH & FITNESS Holism. bisacsh HEALTH & FITNESS Reference. bisacsh MEDICAL Alternative Medicine. bisacsh MEDICAL Atlases. bisacsh MEDICAL Essays. bisacsh MEDICAL Family & General Practice. bisacsh MEDICAL Holistic Medicine. bisacsh MEDICAL Osteopathy. bisacsh Bioengineering fast Biomimetic materials fast Biomimetics fast Biomolecules fast Biotechnology fast Nanotechnology fast
topic_facet	Biotechnology. Biomimetic materials. Biomolecules. Nanotechnology. Biomimetics. Bioengineering. Nanomedicine. Biotechnology Nanotechnology Nanomedicine Nanostructures Biomimetics Biotechnologie. Matériaux biomimétiques. Biomolécules. Chimie biomimétique. Nanotechnologie. Nanomédecine. bioengineering. HEALTH & FITNESS Holism. HEALTH & FITNESS Reference. MEDICAL Alternative Medicine. MEDICAL Atlases. MEDICAL Essays. MEDICAL Family & General Practice. MEDICAL Holistic Medicine. MEDICAL Osteopathy. Bioengineering Biomimetic materials Biomolecules
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=637071
work_keys_str_mv	AT gazitehud plentyofroomforbiologyatthebottomanintroductiontobionanotechnology AT mitrakianna plentyofroomforbiologyatthebottomanintroductiontobionanotechnology

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