دانلود کتاب PrescoTT's Microbiology TENTH

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Prescott’s Microbiology (Joanne M. Willey, Linda M. Sherwood etc.) (z-lib.org)
Cover
Title Page
Copyright Page
Brief Contents
About the Authors
Preface
Contents
Part One Introduction to Microbiology
1 The Evolution of Microorganisms and Microbiology
Micro Focus: Over 4,000 Potential Planets Discovered
1.1 Members of the Microbial World
1.2 Microbes Have Evolved and Diversified for Billions of Years
1.3 Microbiology Advanced as New Tools for Studying Microbes Were Developed
1.4 Microbiology Encompasses Many Subdisciplines
2 Microscopy
Micro Focus: Anthrax Bioterrorism Attack 2001
2.1 Lenses Create Images by Bending Light
2.2 There Are Several Types of Light Microscopes
2.3 Staining Specimens Helps to Visualize and Identify Microbes
2.4 Electron Microscopes Use Beams of Electrons to Create Highly Magnified Images
2.5 Scanning Probe Microscopy Can Visualize Molecules and Atoms
3 Bacterial Cell Structure
Micro Focus: Hooking Up
3.1 Use of the Term \"Prokaryote\" Is Controversial
3.2 Bacteria Are Diverse but Share Some Common Features
3.3 Bacterial Plasma Membranes Control What Enters and Leaves the Cell
3.4 There Are Two Main Types of Bacterial Cell Walls
Microbial Diversity & Ecology 3.1: Gram Positive and Gram Negative or Monoderms and Diderms?
3.5 The Cell Envelope Often Includes Layers Outside the Cell Wall
3.6 The Bacterial Cytoplasm Is More Complex than Once Thought
3.7 Many Bacteria Have External Structures Used for Attachment and Motility
3.8 Bacteria Move in Response to Environmental Conditions
3.9 Bacterial Endospores Are a Survival Strategy
4 Archaeal Cell Structure
Micro Focus: Cows and Buffaloes and Sheep, Oh My!
4.1 Archaea Are Diverse but Share Some Common Features
4.2 Six Major Types of Archaeal Cell Envelopes Have Been Identified
4.3 Archaeal Cytoplasm Is Similar to Bacterial Cytoplasm
4.4 Many Archaea Have External Structures Used for Attachment and Motility
Microbial Diversity & Ecology 4.1: What\'s in a Name?
4.5 Comparison of Bacteria and Archaea
5 Eukaryotic Cell Structure
Micro Focus: Red Means Dead
5.1 Eukaryotic Cells Are Diverse but Share Some Common Features
5.2 Eukaryotic Cell Envelopes
5.3 The Eukaryotic Cytoplasm Contains a Complex Cytoskeleton and Many Membranous Organelles
5.4 Several Cytoplasmic Membranous Organelles Function in the Secretory and Endocytic Pathways
5.5 The Nucleus and Ribosomes Are Involved in Genetic Control of the Cell
5.6 Mitochondria, Related Organelles, and Chloroplasts Are Involved in Energy Conservation
Microbial Diversity & Ecology 5.1: There Was an Old Woman Who Swallowed a Fly
5.7 Many Eukaryotic Microbes Have External Structures Used for Motility
5.8 Comparison of Bacterial, Archaeal, and Eukaryotic Cells
6 Viruses and Other Acellular Infectious Agents
Micro Focus: Mustard, Catsup, and Viruses?
6.1 Viruses Are Acellular
Microbial Diversity & Ecology 6.1: Host-Independent Growth of an Archaeal Virus
6.2 Virion Structure Is Defined by Capsid Symmetry and Presence or Absence of an Envelope
6.3 Viral Life Cycles Have Five Steps
6.4 There Are Several Types of Viral Infections
6.5 Cultivation and Enumeration of Viruses
6.6 Viroids and Satellites: Nucleic Acid-Based Subviral Agents
6.7 Prions Are Composed Only of Protein
Part Two Microbial Nutrition, Growth, and Control
7 Microbial Growth
Micro Focus: Metal or Plastic?
7.1 Most Bacteria and Archaea Reproduce by Binary Fission
7.2 Bacterial Cell Cycles Can Be Divided into Three Phases
7.3 Some Archaeal Cell Cycles Resemble the Eukaryotic Cell Cycle
7.4 Environmental Factors Affect Microbial Growth
7.5 Microbial Growth in Natural Environments
7.6 Laboratory Culture of Cellular Microbes Requires Media and Conditions That Mimic the Normal Habitat of a Microbe
7.7 Growth Curves Consist of Five Phases
7.8 Microbial Population Size Can Be Measured Directly or Indirectly
7.9 Chemostats and Turbidostats Are Used for Continuous Culture of Microorganisms
8 Control of Microorganisms in the Environment
Micro Focus: Bacterial Kamikazes Seek Out and Destroy Pathogens
8.1 Microbial Growth and Replication Pathways: Targets for Control
8.2 The Pattern of Microbial Death Mirrors the Pattern of Microbial Growth
8.3 Mechanical Removal Methods Rely on Barriers
8.4 Physical Control Methods Alter Microorganisms to Make Them Nonviable
8.5 Microorganisms Are Controlled with Chemical Agents
8.6 Antimicrobial Agents Must Be Evaluated for Effectiveness
8.7 Microorganisms Can Be Controlled by Biological Methods
9 Antimicrobial Chemotherapy
Micro Focus: A Teaspoon of Sugar Helps the Bacteria Go Down
9.1 Antimicrobial Chemotherapy Evolved from Antisepsis Efforts
9.2 Antimicrobial Drugs Need to Be Selectively Toxic over a Range of Effectiveness
9.3 Antimicrobial Activity Can Be Measured by Specific Tests
9.4 Antibacterial Drugs
9.5 Antifungal Drugs
9.6 Antiviral Drugs
9.7 Antiprotozoan Drugs
9.8 Several Factors Influence Antimicrobial Drug Effectiveness
Part Three Microbial Metabolism
10 Introduction to Metabolism
Micro Focus: Flushed Away
10.1 Metabolism: Important Principles and Concepts
10.2 ATP: The Major Energy Currency of Cells
10.3 Redox Reactions: Reactions of Central Importance in Metabolism
10.4 Electron Transport Chains: Sets of Sequential Redox Reactions
10.5 Biochemical Pathways: Sets of Linked Chemical Reactions
10.6 Enzymes and Ribozymes Speed Up Cellular Chemical Reactions
10.7 Metabolism Must Be Regulated to Maintain Homeostasis and Prevent Waste
11 Catabolism: Energy Release and Conservation
Micro Focus: The Richest Hill On Earth
11.1 Metabolic Diversity and Nutritional Types
11.2 There Are Three Chemoorganotrophic Fueling Processes
11.3 Aerobic Respiration Can Be Divided into Three Steps
11.4 Glucose to Pyruvate: The First Step
11.5 Pyruvate to Carbon Dioxide (Step 2) Is Accomplished by the Tricarboxylic Acid Cycle
11.6 Electron Transport and Oxidative Phosphorylation (Step 3) Generate the Most ATP
11.7 Anaerobic Respiration Uses the Same Three Steps as Aerobic Respiration
11.8 Fermentation Does Not Involve an Electron Transport Chain
11.9 Catabolism of Organic Molecules Other Than Glucose
11.10 Chemolithotrophy: \"Eating Rocks\"
11.11 Phototrophy
12 Anabolism: The Use of Energy in Biosynthesis
Micro Focus: An Author\'s Life Saved
12.1 Principles Governing Biosynthesis
12.2 Precursor Metabolites: Starting Molecules for Biosynthesis
12.3 CO2 Fixation: Reduction and Assimilation of CO2 Carbon
12.4 Synthesis of Carbohydrates
12.5 Synthesis of Amino Acids Consumes Many Precursor Metabolites
12.6 Synthesis of Purines, Pyrimidines, and Nucleotides
12.7 Lipid Synthesis
Part Four Microbial Molecular Biology and Genetics
13 Bacterial Genome Replication and Expression
Micro Focus: Making Code
13.1 Experiments Using Bacteria and Viruses Demonstrated that DNA Is the Genetic Material
13.2 Nucleic Acid and Protein Structure
13.3 DNA Replication in Bacteria
13.4 Bacterial Genes Consist of Coding Regions and Other Sequences Important for Gene Function
13.5 Transcription in Bacteria
13.6 The Genetic Code Consists of Three-Letter \"Words\"
13.7 Translation in Bacteria
13.8 Protein Maturation and Secretion
14 Regulation of Bacterial Cellular Processes
Micro Focus: Letting Go
14.1 Bacteria Use Many Regulatory Options
14.2 Regulation of Transcription Initiation Saves Considerable Energy and Materials
14.3 Attenuation and Riboswitches Can Stop Transcription Prematurely
14.4 Riboswitches and Small RNAs Can Control Translation
14.5 Bacteria Combine Several Regulatory Mechanisms to Control Complex Cellular Processes
15 Eukaryotic and Archaeal Genome Replication and Expression
Micro Focus: Plastics: Brought to You by Microbes
15.1 Why Consider Eukaryotic and Archaeal Genetics Together?
15.2 DNA Replication: Similar Overall, but with Different Replisome Proteins
15.3 Transcription
15.4 Translation and Protein Maturation and Localization
15.5 Regulation of Cellular Processes
16 Mechanisms of Genetic Variation
Micro Focus: Manure Happens
16.1 Mutations: Heritable Changes in a Genome
16.2 Detection and Isolation of Mutants
16.3 DNA Repair Maintains Genome Stability
16.4 Microbes Use Mechanisms Other than Mutation to Create Genetic Variability
16.5 Transposable Elements Move Genes Within and Between DNA Molecules
16.6 Bacterial Conjugation Requires Cell-Cell Contact
16.7 Bacterial Transformation Is the Uptake of Free DNA from the Environment
16.8 Transduction Is Virus-Mediated DNA Transfer
16.9 Evolution in Action: The Development of Antibiotic Resistance in Bacteria
17 Recombinant DNA Technology
Micro Focus: Archeological Digs Reveal Source of Ancient Pathogen
17.1 Key Discoveries Led to the Development of Recombinant DNA Technology
Techniques & Applications 17.1: Streptavidin-Biotin Binding and Biotechnology
17.2 Polymerase Chain Reaction Amplifies Targeted DNA
17.3 Cloning Vectors Are Needed to Create Recombinant DNA
17.4 Introducing Recombinant DNA into Host Cells
Techniques & Applications 17.2: How to Build a Microorganism
17.5 Genomic Libraries: Cloning Genomes in Pieces
17.6 Expressing Foreign Genes in Host Cells
18 Microbial Genomics
Micro Focus: \"Synthetic Life\": Oxymoron or the Future?
18.1 DNA Sequencing Methods
18.2 Genome Sequencing
18.3 Metagenomics Provides Access to Uncultured Microbes
18.4 Bioinformatics: What Does the Sequence Mean?
18.5 Functional Genomics Links Genes to Phenotype
18.6 Systems Biology: Making and Testing Complex Predictions
18.7 Comparative Genomics
Part Five The Diversity of the Microbial World
19 Microbial Taxonomy and the Evolution of Diversity
Micro Focus: Scientists Query: \"Is the Microbial Universe Expanding?\"
19.1 Microbial Taxonomy Is Based on the Evolution of Multiple Traits
19.2 Taxonomic Ranks Provide an Organizational Framework
19.3 Microbial Taxonomy and Phylogeny Are Largely Based on Molecular Characterization
19.4 Phylogenetic Trees Illustrate Evolutionary Relationships
19.5 Evolutionary Processes and the Concept of a Microbial Species Inspire Debate
19.6 Bergey\'s Manual of Systematic Bacteriology
20 Archaea
Micro Focus: Methanogenic Archaea Fuel Domestic Energy Debate
20.1 Overview of Archaea
20.2 Phylum Crenarchaeota: Metabolically Diverse Thermophiles
20.3 Phylum Thaumarchaeota: Mesophilic Ammonia Oxidizers
20.4 Phylum Euryarchaeota: Methanogens, Haloarchaea, and Others
21 Deinococci, Mollicutes, and Nonproteobacterial Gram-Negative Bacteria
Micro Focus: Cyanobacteria Stimulate Broad Appeal for Biofuel Production
21.1 Aquificae and Thermotogae Are Ancient Bacterial Lineages
21.2 Deinococcus-Thermus Includes Radiation-Resistant Bacteria
21.3 Class Mollicutes, Phylum Tenericutes: Bacteria That Lack Cell Walls
21.4 Photosynthetic Bacteria Are Diverse
21.5 Phylum Planctomycetes: Bacteria with Intracellular Compartments
21.6 Phylum Chlamydiae: Obligate Intracellular Parasites
21.7 Phylum Verrucomicrobia Includes Human Symbionts and Methylotrophs
21.8 Phylum Spirochaetes: Bacteria with a Corkscrew Morphology
21.9 Phylum Bacteroidetes Includes Important Gut Microbiota
22 Proteobacteria
Micro Focus: Bison and Brucellosis Spark Controversy
22.1 Class Alphaproteobacteria Includes Many Oligotrophs
22.2 Class Betaproteobacteria Includes Chemoheterotrophs and Chemolithotrophs
Microbial Diversity & Ecology 22.1: Acid Mine Drainage
22.3 Class Gammaproteobacteria Is the Largest Bacterial Class
Microbial Diversity & Ecology 22.2: Bacterial Bioluminescence
22.4 Class Deltaproteobacteria Includes Chemoheterotrophic Anaerobes and Predators
22.5 Class Epsilonproteobacteria Ranges from Pathogens to Deep-Sea Bacteria
23 Firmicutes: The Low G 1 C Gram-Positive Bacteria
Micro Focus: Invasive Strep Strikes Young, Old, and Famous
23.1 Class Clostridia: Anaerobic Endospore-Forming Bacteria
23.2 Class Negativicutes: Gram-Positive Bacteria with Outer Membranes
23.3 Class Bacilli: Aerobic Endospore- Forming Bacteria
24 Actinobacteria: The High G + C Gram-Positive Bacteria
Micro Focus: Antibiotic Production: Is it Actually Bacterial Chit-Chat?
24.1 Class Actinobacteria
25 Protists
Micro Focus: Sustainable Farming Practiced by Amoebae
25.1 Protist Diversity Reflects Broad Phylogeny
25.2 Supergroup Excavata: Primitive Eukaryotes
25.3 Supergroup Amoebozoa Includes Protists with Pseudopodia
25.4 Supergroup SAR: Protists of Great Importance
25.5 Supergroup Archaeplastida Includes \"Green Algae\"
26 Fungi (Eumycota)
Micro Focus: Fungi May Be Key to Quelling Malaria
26.1 Fungal Biology Reflects Vast Diversity
26.2 Chytridiomycota Produce Motile Spores
26.3 Zygomycota: Fungi with Coenocytic Hyphae
26.4 Glomeromycota Are Mycorrhizal Symbionts
26.5 Ascomycota Includes Yeasts and Molds
26.6 Basidiomycota Includes Mushrooms and Plant Pathogens
Disease 26.1: White-Nose Syndrome Is Decimating North American Bat Populations
26.7 Microsporidia Are Intracellular Parasites
27 Viruses
Micro Focus: Deadly New Virus Strikes European Farm Animals
27.1 Virus Phylogeny Is Difficult to Establish
27.2 Double-Stranded DNA Viruses Infect All Cell Types
Microbial Diversity & Ecology 27.1: What Is a Virus?
27.3 Single-Stranded DNA Viruses Use a Double-Stranded Intermediate in Their Life Cycles
27.4 Double-Stranded RNA Viruses: RNA-Dependent RNA Polymerase Replicates the Genome and Synthesizes mRNA
27.5 Plus-Strand RNA Viruses: Genomes That Can Be Translated upon Entry
27.6 Minus-Strand RNA Viruses: RNA-Dependent RNA Polymerase Is Part of the Virion
27.7 Retroviruses: Plus-Strand Viruses That Use Reverse Transcriptase in Their Life Cycles
27.8 Reverse Transcribing DNA Viruses
Part Six Ecology and Symbiosis
28 Biogeochemical Cycling and Global Climate Change
Micro Focus: Global Climate Change Global Infectious Disease Change?
28.1 Biogeochemical Cycling Sustains Life on Earth
28.2 Global Climate Change: Biogeochemical Cycling Out of Balance
29 Methods in Microbial Ecology
Micro Focus: Scientists Search for Intraterrestrial Life-and Find It
29.1 Microbial Biology Relies on Cultures
29.2 Genetic Methods Are Used to Assess Microbial Diversity
29.3 Assessment of Microbial Community Activity Relies on Biochemistry and Genetics
30 Microorganisms in Marine and Freshwater Ecosystems
Micro Focus: Ocean Death Coming Soon to a Coast Near you
30.1 Water Is the Largest Microbial Habitat
30.2 Microorganisms in Marine Ecosystems
30.3 Microorganisms in Freshwater Ecosystems
31 Microorganisms in Terrestrial Ecosystems
Micro Focus: A Short History of Rust
31.1 Soils Are an Important Microbial Habitat
31.2 Diverse Microorganisms Inhabit Soil
31.3 Microbe-Plant Interactions Can Be Positive, Negative, or Neutral
31.4 The Subsurface Biosphere Is Vast
32 Microbial Interactions
Micro Focus: Embrace Your Gut Flora, for You Know Not What They Do
32.1 Many Types of Microbial Interactions Exist
Microbial Diversity & Ecology 32.1: Wolbachia pipientis: The World\'s Most Infectious Microbe?
32.2 The Human-Microbe Ecosystem
Microbial Diversity & Ecology 32.2: Do Bacteria Make People Fat?
32.3 Normal Microbiota of the Human Body Adapt to the Human Condition
Part Seven Pathogenicity and Host Response
33 Innate Host Resistance
Micro Focus: Supersize Me!
33.1 Immunity Arises from Innate Resistance and Adaptive Defenses
33.2 Innate Resistance Starts with Barriers
33.3 Innate Resistance Relies on Chemical Mediators
33.4 Cells, Tissues, and Organs Work Collectively to Form an Immune System
33.5 Phagocytosis: Destroying Invaders and Recycling Their Parts
33.6 Inflammation Unites All the Components of Immunity
34 Adaptive Immunity
Micro Focus: It\'s in My Genes?
34.1 Adaptive Immunity Relies on Recognition and Memory
34.2 Molecules That Elicit Immunity Are Called Antigens
34.3 Adaptive Immunity Can Be Earned or Borrowed
34.4 Recognition of Foreignness Is Critical for a Strong Defense
34.5 T Cells Oversee and Participate in Immune Functions
34.6 B Cells Make Antibodies and Do a Whole Lot More
34.7 Antibodies Are Proteins That Bind to Specific 3-D Molecules
34.8 Antibody Binding Dooms the Target
Techniques & Applications 34.1: Monoclonal Antibody Therapy
34.9 Not Responding Is Also Part of Immunity
34.10 Sometimes the Immune System Doesn\'t Work the Way It Should
35 Pathogenicity and Infection
Micro Focus: Sneaky Little Buggers
35.1 Pathogenicity Drives Infectious Disease
35.2 Virulence Defines a Pathogen\'s Success
35.3 Exposure and Transmission Can Lead to Infectious Disease
Historical Highlights 35.1: The First Indications of Person-to-Person Spread of an Infectious Disease
Part Eight Microbial Diseases, Detection, and Their Control
36 Clinical Microbiology and Immunology
Micro Focus: Seeing the Next Frontier
36.1 The Clinical Microbiology Laboratory Is the Front Line for Infectious Disease Detection
36.2 Biosafety Practices Protect Lab Workers
36.3 Identification of Microorganisms from Specimens
36.4 Immune Responses Can Be Measured or Exploited to Detect Infections
37 Epidemiology and Public Health Microbiology
Micro Focus: Practice What You Preach
37.1 Epidemiology Is an Evidence-Based Science
Historical Highlights 37.1: The Birth of Public Health in the United States
Historical Highlights 37.2: John Snow, the First Epidemiologist
37.2 Epidemiology Is Rooted in Well-Tested Methods
Historical Highlights 37.3: A Modern Epidemic Exposed
37.3 Infectious Disease Is Revealed Through Patterns Within a Population
Historical Highlights 37.4: \"Typhoid Mary\"
37.4 Infectious Diseases and Pathogens Are Emerging and Reemerging
37.5 Health-Care Facilities Harbor Infectious Agents
37.6 Coordinated Efforts Are Required to Prevent and Control Epidemics
Historical Highlights 37.5: The First Immunizations
37.7 Bioterrorism Readiness Is an Integral Component of Public Health Microbiology
Historical Highlights 37.6: 1346-The First Recorded Biological Warfare Attack
38 Human Diseases Caused by Viruses and Prions
Micro Focus: Honest . . . It Was the Mosquito!
38.1 Viruses Can Be Transmitted by Airborne Routes
38.2 Arthropods Can Transmit Viral Diseases
38.3 Direct Contact Diseases Can Be Caused by Viruses
38.4 Food and Water Are Vehicles for Viral Diseases
Historical Highlights 38.1: A Brief History of Polio
38.5 Zoonotic Diseases Arise from Human-Animal Interactions
38.6 Prion Proteins Transmit Disease
39 Human Diseases Caused by Bacteria
Micro Focus: \"This Little Piggie Stayed Home\"
39.1 Bacteria Can Be Transmitted by Airborne Routes
39.2 Arthropods Can Transmit Bacterial Diseases
39.3 Direct Contact Diseases Can Be Caused by Bacteria
Disease 39.1: A Brief History of Syphilis
Disease 39.2: Biofilms
39.4 Food and Water Are Vehicles for Bacterial Diseases
Techniques & Applications 39.3: Clostridial Toxins as Therapeutic Agents: Benefits of Nature\'s Most Toxic Proteins
39.5 Zoonotic Diseases Arise from Human-Animal Interactions
39.6 Opportunistic Diseases Can Be Caused by Bacteria
40 Human Diseases Caused by Fungi and Protists
Micro Focus: Death by-Mushroom?
40.1 Relatively Few Fungi and Protists Are Human Pathogens
40.2 Fungi and Protists Can Be Transmitted by Airborne Routes
Disease 40.1: A Brief History of Malaria
40.3 Arthropods Can Transmit Fungal and Protozoal Disease
40.4 Direct Contact Diseases Can Be Caused by Fungi and Protists
40.5 Food and Water Are Vehicles of Fungal and Protozoal Diseases
40.6 Opportunistic Diseases Can Be Caused by Fungi and Protists
Part Nine Applied Microbiology
41 Microbiology of Food
Micro Focus: The Art, Science, and Genetics of Brewing Beer
41.1 Microbial Growth Can Cause Food Spoilage
41.2 Various Methods Are Used to Control Food Spoilage
41.3 Food-Borne Disease Outbreaks
41.4 Detection of Food-Borne Pathogens Requires Government-Industry Cooperation
41.5 Microbiology of Fermented Foods: Beer, Cheese, and Much More
Techniques & Applications 41.1: Chocolate: The Sweet Side of Fermentation
41.6 Probiotics
42 Biotechnology and Industrial Microbiology
Micro Focus: Where Are the New Antibiotics?
42.1 Microbes Are the Source of Many Products of Industrial Importance
42.2 Biofuel Production Is a Dynamic Field
42.3 Growing Microbes in Industrial Settings Presents Challenges
42.4 Production Strains Are Developed to Maximize Output of Industrially Important Compounds
42.5 Agricultural Biotechnology Relies on a Plant Pathogen
42.6 Some Microbes Are Products
43 Applied Environmental Microbiology
Micro Focus: Deepwater Horizon Oil Consumed by Microbes
43.1 Purification and Sanitary Analysis Ensure Safe Drinking Water
43.2 Wastewater Treatment Maintains Human and Environmental Health
43.3 Microbial Fuel Cells: Batteries Powered by Microbes
43.4 Biodegradation and Bioremediation Harness Microbes to Clean the Environment
Appendix 1 A Review of the Chemistry of Biological Molecules
Appendix 2 Common Metabolic Pathways
Appendix 3 Microorganism Pronunciation Guide
Glossary
Credits
Index
David Icke - Perceptions of a Renegade Mind-David Icke Books (2021) copy
Copyright
Title Page
Dedication
Contents
Chapter 1: ‘I’m thinking’ – Oh, but are you?
Chapter 2: Renegade perception
Chapter 3: The Pushbacker sting
Chapter 4: ‘Covid’: The calculated catastrophe
Chapter 5: There is no ‘virus’
Chapter 6: Sequence of deceit
Chapter 7: War on your mind
Chapter 8: ‘Reframing’ insanity
Chapter 9: We must have it? So what is it?
Chapter 10: Human 2.0
Chapter 11: Who controls the Cult?
Chapter 12: Escaping Wetiko
Postscript
Appendix: Cowan-Kaufman-Morell Statement on Virus Isolation
Bibliography
Index
David Icke - Perceptions of a Renegade Mind-David Icke Books (2021)
Copyright
Title Page
Dedication
Contents
Chapter 1: ‘I’m thinking’ – Oh, but are you?
Chapter 2: Renegade perception
Chapter 3: The Pushbacker sting
Chapter 4: ‘Covid’: The calculated catastrophe
Chapter 5: There is no ‘virus’
Chapter 6: Sequence of deceit
Chapter 7: War on your mind
Chapter 8: ‘Reframing’ insanity
Chapter 9: We must have it? So what is it?
Chapter 10: Human 2.0
Chapter 11: Who controls the Cult?
Chapter 12: Escaping Wetiko
Postscript
Appendix: Cowan-Kaufman-Morell Statement on Virus Isolation
Bibliography
Index