Prescott's microbiology / (Record no. 45191)
[ view plain ]
| 000 -LEADER | |
|---|---|
| fixed length control field | 21358nam a2200397 i 4500 |
| 003 - CONTROL NUMBER IDENTIFIER | |
| control field | CaONFJC |
| 005 - DATE AND TIME OF LATEST TRANSACTION | |
| control field | 20250813163638.0 |
| 008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION | |
| fixed length control field | 220428s2022 nyuab fo 001|0 eng d |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER | |
| International Standard Book Number | 9781265732295 |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER | |
| Cancelled/invalid ISBN | 9781265123031 |
| 041 ## - LANGUAGE CODE | |
| Language | English |
| 082 04 - DEWEY DECIMAL CLASSIFICATION NUMBER | |
| Classification number | 579 |
| Edition number | 23 |
| Item number | WIL |
| 100 1# - MAIN ENTRY--PERSONAL NAME | |
| Personal name | Willey, Joanne M., |
| 245 10 - TITLE STATEMENT | |
| Title | Prescott's microbiology / |
| Statement of responsibility, etc | Joanne M. Willey, Hofstra University, Kathleen M. Sandman, Dorothy H. Wood, Education & Training Systems International. |
| 250 ## - EDITION STATEMENT | |
| Edition statement | Twelfth edition. |
| 260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) | |
| Place of publication, distribution, etc | New York : |
| Name of publisher, distributor, etc | McGraw Hill LLC, |
| Date of publication, distribution, etc | 2023. |
| 300 ## - PHYSICAL DESCRIPTION | |
| Other physical details | illustrations (black and white, and colour), maps (colour) |
| 500 ## - GENERAL NOTE | |
| General note | Includes index. |
| 505 ## - FORMATTED CONTENTS NOTE | |
| Title | Cover<br/>Title Page<br/>Copyright Page<br/>Brief Contents<br/>Connect Page<br/>Digital Tools for Your Success<br/>A Modern Approach to Microbiology<br/>Student-Friendly Organization<br/>List of Content Changes<br/>About the Authors<br/>Acknowledgements<br/>Contents<br/>1 The Evolution of Microorganisms and Microbiology<br/>Microbiology’s Reach<br/>1.1 Members of the Microbial World<br/>1.2 Microbes Have Evolved and Diversified for Billions of Years<br/> Microbial Diversity & Ecology 1.1<br/> Hydrothermal Vents: Did Life Begin Under the Sea?<br/>1.3 Microbiology Advanced as New Tools for Studying Microbes Were Developed<br/>1.4 Microbiology Encompasses Many Subdisciplines<br/>2 Microscopy<br/>Anthrax Bioterrorism Attack<br/>2.1 Lenses Create Images by Bending Light<br/>2.2 There Are Several Types of Light Microscopes<br/>2.3 Staining Helps to Visualize and Identify Microbes<br/>2.4 Electron Microscopes Use Beams of Electrons to Create Highly Magnified Images<br/>2.5 Scanning Probe Microscopy Can Visualize Molecules and Atoms<br/>3 Bacterial Cell Structure<br/>Bacteria Use Rapid Transport<br/>3.1 Use of the Term “Prokaryote” Is Controversial<br/>3.2 Bacteria Are Diverse but Share Some Common Features<br/>3.3 Bacterial Plasma Membranes Control What Enters and Leaves the Cell<br/>3.4 Cell Walls Have Many Functions<br/>3.5 Extracellular Vesicles Emerge from Bacterial Membranes<br/>3.6 The Cell Envelope Often Includes Layers Outside the Cell Wall<br/>3.7 The Bacterial Cytoplasm Is More Complex than Once Thought<br/> Microbial Diversity & Ecology 3.1<br/> Organelles Without Membranes?<br/>3.8 External Structures Are Used for Attachment and Motility<br/>3.9 Bacteria Move in Response to Environmental Conditions<br/>3.10 Bacterial Endospores Are a Survival Strategy<br/>4 Archaeal Cell Structure<br/>Methane—The Other Greenhouse Gas<br/>4.1 Archaea Are Diverse but Share Some Common Features<br/>4.2 Archaeal Cell Envelopes Are Structurally Diverse<br/>4.3 Archaeal Cytoplasm Is Similar to Bacterial Cytoplasm<br/>4.4 Many Archaea Have External Structures Used for Attachment and Motility<br/>5 Eukaryotic Cell Structure<br/>Red Means Dead<br/>5.1 Eukaryotic Cells Are Diverse but Share Some Common Features<br/>5.2 Eukaryotic Cell Envelopes<br/>5.3 The Eukaryotic Cytoplasm Contains a Cytoskeleton and Organelles<br/>5.4 Several Organelles Function in the Secretory and Endocytic Pathways<br/>5.5 The Nucleus and Ribosomes Are Involved in Genetic Control of the Cell<br/>5.6 Mitochondria, Related Organelles, and Chloroplasts Are Involved in Energy Conservation<br/> Microbial Diversity & Ecology 5.1<br/> There Was an Old Woman Who Swallowed a Fly<br/>5.7 Many Eukaryotic Microbes Have External Structures Used for Motility<br/>6 Viruses and Other Acellular Infectious Agents<br/>Viruses to the Rescue<br/>6.1 Viruses Are Acellular<br/>6.2 Virion Structure Is Defined by Capsid Symmetry and Presence or Absence of an Envelope<br/>6.3 Viral Life Cycles Have Five Steps<br/>6.4 There Are Several Types of Viral Infections<br/>6.5 Virus Cultivation and Enumeration<br/>6.6 Viroids and Satellites: Nucleic Acid-Based Subviral Agents<br/>6.7 Prions Are Composed Only of Protein<br/>7 Bacterial and Archaeal Growth<br/>How Low Can You Go?<br/>7.1 Most Bacteria and Archaea Reproduce by Binary Fission<br/>7.2 Bacterial Cell Cycles Are Divided into Three Phases<br/>7.3 Archaeal Cell Cycles Are Unique<br/>7.4 Growth Curves Consist of Five Phases<br/>7.5 Environmental Factors Affect Microbial Growth<br/> Microbial Diversity & Ecology 7.1<br/> Microbial Sculptors<br/>7.6 Microbial Growth in Natural Environments<br/>7.7 Laboratory Culture of Microbes Requires Conditions that Mimic Their Normal Habitats<br/>7.8 Microbial Population Size Can Be Measured Directly or Indirectly<br/>7.9 Chemostats and Turbidostats Are Used for Continuous Culture of Microorganisms<br/>8 Control of Microorganisms in the Environment<br/>To Wipe or Not to Wipe? That Is the Question.<br/>8.1 Microbial Growth and Replication: Targets for Control<br/>8.2 Microbes Can Be Controlled by Physical Means<br/> Techniques & Applications 8.1<br/> Come Fly with Me?<br/>8.3 Microorganisms Are Controlled with Chemical Agents<br/>8.4 Antimicrobial Agents Must Be Evaluated for Effectiveness<br/>8.5 Microorganisms Can Be Controlled by Biological Methods<br/>9 Antimicrobial Chemotherapy<br/>A Gift from Traditional Chinese Medicine<br/>9.1 Antimicrobial Chemotherapy Evolved from Antisepsis Efforts<br/>9.2 Antimicrobial Drugs Have Selective Toxicity<br/>9.3 Antimicrobial Activity Can Be Measured by Specific Tests<br/>9.4 Antibacterial Drugs<br/>9.5 Antiviral Drugs<br/>9.6 Antifungal Drugs<br/>9.7 Antiprotozoan Drugs<br/> Disease 9.1<br/> Chloroquine and COVID-19: A Cautionary Tale<br/>9.8 Antimicrobial Drug Resistance Is a Public Health Threat<br/>10 Introduction to Metabolism<br/>Flushed Away<br/>10.1 Metabolism: Important Principles and Concepts<br/>10.2 ATP: The Major Energy Currency of Cells<br/>10.3 Redox Reactions: Reactions of Central Importance in Metabolism<br/>10.4 Electron Transport Chains: Sets of Sequential Redox Reactions<br/>10.5 Biochemical Pathways: Sets of Linked Chemical Reactions<br/>10.6 Enzymes and Ribozymes Speed Up Cellular Chemical Reactions<br/>10.7 Metabolism Must Be Regulated to Maintain Homeostasis<br/>11 Catabolism: Energy Release and Conservation<br/>The Richest Hill on Earth<br/>11.1 Metabolic Diversity and Nutritional Types<br/>11.2 There Are Two Chemoorganotrophic Fueling Processes<br/>11.3 Aerobic Respiration Starts with Glucose Oxidation<br/>11.4 Electron Transport and Oxidative Phosphorylation Generate the Most ATP<br/>11.5 Anaerobic Respiration Uses the Same Steps as Aerobic Respiration<br/>11.6 Fermentation Does Not Involve an Electron Transport Chain<br/>11.7 Catabolism of Organic Molecules Other than Glucose<br/>11.8 Chemolithotrophy: “Eating Rocks”<br/>11.9 Flavin-Based Electron Bifurcation<br/>11.10 Phototrophy<br/>12 Anabolism: The Use of Energy in Biosynthesis<br/>Building Penicillin<br/>12.1 Principles Governing Biosynthesis<br/>12.2 Precursor Metabolites: Starting Molecules for Biosynthesis<br/>12.3 CO2 Fixation: Reduction and Assimilation of CO2 Carbon<br/>12.4 Synthesis of Carbohydrates<br/>12.5 Synthesis of Amino Acids Consumes Many Precursor Metabolites<br/>12.6 Synthesis of Purines, Pyrimidines, and Nucleotides<br/>12.7 Lipid Synthesis<br/>13 Bacterial Genome Replication and Expression<br/>Making Code<br/>13.1 Experiments Using Bacteria and Viruses Demonstrated that DNA Is the Genetic Material<br/>13.2 Nucleic Acid and Protein Structure<br/>13.3 DNA Replication in Bacteria<br/>13.4 Bacterial Genes Consist of Coding Regions and Other Sequences Important for Gene Function<br/>13.5 Transcription in Bacteria<br/>13.6 The Genetic Code Consists of Three-Letter “Words”<br/>13.7 Translation in Bacteria<br/>13.8 Coordination of Gene Expression Processes<br/>13.9 Protein Maturation and Secretion<br/>14 Regulation of Cellular Processes<br/>Promoting Expression<br/>14.1 Bacteria Use Many Regulatory Strategies<br/>14.2 Regulation of Transcription Initiation Saves Considerable Energy and Materials<br/>14.3 Attenuation and Riboswitches Stop Transcription Prematurely<br/>14.4 RNA Secondary Structures Control Translation<br/>14.5 Mechanisms Used for Global Regulation<br/>14.6 Bacteria Combine Several Regulatory Mechanisms to Control Complex Cellular Processes<br/>15 Eukaryotic and Archaeal Genome Replication and Expression<br/>Pharming<br/>15.1 Genetic Processes in the Three Domains<br/>15.2 DNA Replication: Similar Overall, but with Different Replisome Proteins<br/>15.3 Transcription<br/>15.4 Translation and Protein Maturation and Localization<br/>15.5 Regulation of Cellular Processes<br/>16 Mechanisms of Genetic Variation<br/>Manure Happens<br/>16.1 Mutations: Heritable Changes in a Genome<br/>16.2 Detection and Isolation of Mutants<br/>16.3 DNA Repair Maintains Genome Stability<br/>16.4 Microbes Use Mechanisms Other than Mutation to Create Genetic Variability<br/>16.5 Mobile Genetic Elements Move Genes Within and Between DNA Molecules<br/>16.6 Conjugation Requires Cell-Cell Contact<br/>16.7 Transformation Is the Uptake of Free DNA<br/>16.8 Transduction Is Virus-Mediated DNA Transfer<br/>16.9 Evolution in Action: The Development of Antibiotic Resistance in Bacteria<br/>17 Microbial DNA Technologies<br/>Spinning Stronger Silk<br/>17.1 Key Discoveries Led to the Development of DNA Cloning Technology<br/> Techniques & Applications 17.1<br/> Gel Electrophoresis<br/>17.2 Polymerase Chain Reaction Amplifies Targeted DNA<br/>17.3 Genomic and Metagenomic Libraries: Cloning Genomes in Pieces<br/>17.4 Expressing Foreign Genes in Host Cells<br/>17.5 Cas9 Nuclease Is a Programmable Tool for Genome Editing<br/>17.6 Biotechnology Develops Custom Microbes for Industrial Use<br/> Techniques & Applications 17.2<br/> How to Build a Microorganism<br/>18 Microbial Genomics<br/>What’s in a Genome?<br/>18.1 DNA Sequencing Methods<br/>18.2 Genome Sequencing<br/>18.3 Metagenomics Provides Access to Uncultured Microbes<br/>18.4 Bioinformatics: What Does the Sequence Mean?<br/>18.5 Functional Genomics Links Genes to Phenotype<br/>18.6 Systems Biology: Making and Testing Complex Predictions<br/>18.7 Comparative Genomics<br/>19 Archaea<br/>Methanogens Fuel Domestic Energy Debate<br/>19.1 Overview of Archaea<br/>19.2 Phyla Asgardarchaeota and Nanoarchaeota Are Known Primarily from Metagenomics<br/>19.3 Phylum Thermoproteota: Sulfur-Dependent Thermophiles<br/>19.4 Phylum Nitrosphaeria: Mesophilic Ammonia Oxidizers<br/>19.5 Phyla Methanobacteriota, Halobacteriota, and Thermoplasmatota: Methanogens, Haloarchaea, and Others<br/>20 Nonproteobacterial Gram-Negative Bacteria<br/>From Food Waste to Fuel<br/>20.1 Diderm Cell Envelopes Are Not Uniform<br/>20.2 Aquificota and Thermotogota Are Hyperthermophiles<br/>20.3 Deinococcota Includes Radiation-Resistant Bacteria<br/>20.4 Photosynthetic Bacteria Are Diverse<br/>20.5 PVC Superphylum (Planctomycetota and Verrucomicrobiota): Atypical Cell Division<br/>20.6 Phylum Spirochaetota: Bacteria with a Corkscrew Morphology<br/>20.7 Phylum Bacteroidota Includes Important Gut Microbiota<br/>20.8 Phylum Fusobacteriota: Commensal Anaerobes<br/>20.9 Phylum Desulfobacterota: Anaerobic Sulfate/Sulfur Reducers<br/>20.10 Phyla Bdellovibrionota and Myxococcota: Bacterial Predators<br/>20.11 Phylum Campylobacterota: Human and Animal Commensals<br/>21 Proteobacteria<br/>Bison and Brucellosis Spark Controversy<br/>21.1 Class Alphaproteobacteria Includes Many Oligotrophs<br/>21.2 Gammaproteobacteria Is the Largest Bacterial Class<br/> Microbial Diversity & Ecology 21.1<br/> Acid Mine Drainage<br/>22 Gram-Positive Bacteria<br/>Antibiotic Production: Is It Actually Bacterial Chitchat?<br/>22.1 Phylum Actinobacteriota<br/>22.2 Phylum Firmicutes, Class Bacilli: Aerobic Endospore-Forming Bacteria<br/>22.3 Phylum Firmicutes, Class Clostridia: Anaerobic Endospore-Forming Bacteria<br/>22.4 Phylum Firmicutes, Classes Negativicutes and Halanaerobiia: Gram-Positive Bacteria with Outer Membranes<br/>23 Protists<br/>Setting the Record Straight<br/>23.1 Protist Diversity Reflects Broad Phylogeny<br/>23.2 Discoba-Metamonada Clade<br/>23.3 Amoebozoa Clade Includes Protists with Pseudopodia<br/>23.4 TSAR Clade: Protists of Global Importance<br/>23.5 Haptista Clade<br/>23.6 Archaeplastida Clade Includes Green and Red Algae<br/>24 Fungi<br/>The Complex Story of Caterpillar Fungus<br/>24.1 Fungal Biology Reflects Vast Diversity<br/>24.2 Zoosporic Fungi Produce Motile Spores<br/>24.3 Zygomycetous Fungi Have Coenocytic Hyphae<br/>24.4 Dikarya Is the Most Diverse Fungal Group<br/> Disease 24.1<br/> White-Nose Syndrome Is Decimating North American Bat Populations<br/>25 Viruses<br/>Disrupting the Viral Life Cycle<br/>25.1 Virus Phylogeny Relies on Genomics<br/>25.2 Double-Stranded DNA Viruses Infect All Cell Types<br/>25.3 Single-Stranded DNA Viruses Use a Double-Stranded Intermediate in Their Life Cycles<br/>25.4 Double-Stranded RNA Viruses: RNADependent RNA Polymerase Replicates the Genome and Synthesizes mRNA<br/>25.5 Positive-Strand RNA Viruses: Genomes that Are Translated upon Entry<br/>25.6 Negative-Strand RNA Viruses: RNA-Dependent RNA Polymerase Is Part of the Virion<br/>25.7 Retroviruses: Positive-Strand Viruses that Use Reverse Transcriptase in Their Life Cycles<br/>25.8 Reverse Transcribing DNA Viruses<br/>26 Exploring Microbes in Ecosystems<br/>Scientists Search for Intraterrestrial Life—and Find It<br/>26.1 Microbial Biology Relies on Cultures<br/> Microbial Diversity & Ecology 26.1<br/> Patience, Hard Work, Luck, and the Evolution of Eukaryotes<br/>26.2 Microbial Identification Is Largely Based on Molecular Characterization<br/>26.3 Assessing Microbial Populations<br/>26.4 Assessing Microbial Community Activity<br/>27 Microbial Interactions<br/>Microbes in Community<br/>27.1 Many Types of Microbial Interactions Exist<br/>27.2 Mutualism: Obligatory Positive Interaction<br/>27.3 Cooperation: Nonobligatory Positive Interaction<br/>27.4 Antagonistic Interactions Prompt Microbial Responses<br/> Microbial Diversity & Ecology 27.1<br/> Wolbachia: The World’s Most Infectious Microbe?<br/>28 Biogeochemical Cycling and Global Climate Change<br/>Global Climate Change; Infectious Disease Change<br/>28.1 Biogeochemical Cycling Sustains Life on Earth<br/>28.2 Microbes Mediate Nutrient Cycling<br/>28.3 Global Climate Change: Infectious Disease Change<br/>29 Microorganisms in Marine and Freshwater Ecosystems<br/>Ocean Death Coming Soon to a Coast Near You<br/>29.1 Water Is the Largest Microbial Habitat<br/>29.2 Microorganisms in Marine Ecosystems<br/>29.3 Microorganisms in Freshwater Ecosystems<br/> Microbial Diversity & Ecology 29.1<br/> Attention All Dog Owners!<br/>30 Microorganisms in Terrestrial Ecosystems<br/>Bread for a Hungry World<br/>30.1 Soils Are an Important Microbial Habitat<br/>30.2 Diverse Microorganisms Inhabit Soil<br/>30.3 Microbe-Plant Interactions Can Be Positive, Negative, or Neutral<br/> Disease 30.1<br/> Citrus Greening and the Power of “Why?”<br/>30.4 The Subsurface Biosphere Is Vast<br/>31 Innate Host Resistance<br/>The Hygiene Hypothesis<br/>31.1 Immunity Arises from Innate Resistance and Adaptive Defenses<br/>31.2 Innate Resistance Starts with Barriers<br/>31.3 Innate Resistance Relies on Chemical Mediators<br/>31.4 Each Type of Innate Immune Cell Has a Specific Function<br/>31.5 Organs and Tissues of the Immune System Are Sites of Host Defense<br/>31.6 Phagocytosis Destroys Invaders<br/>31.7 Inflammation Unites All Components of Immunity<br/>32 Adaptive Immunity<br/>Killing Cancer, Immunologically<br/>32.1 Adaptive Immunity Relies on Recognition and Memory<br/>32.2 Antigens Elicit Immunity<br/>32.3 Adaptive Immunity Can Be Earned or Borrowed<br/>32.4 Recognition of Foreignness Is Critical for a Strong Defense<br/>32.5 T Cells Are Critical for Immune Function<br/>32.6 B Cells Make Antibodies<br/>32.7 Antibodies Bind Specific 3-D Antigens<br/> Techniques & Applications 32.1<br/> Monoclonal Antibody Therapy<br/>32.8 Antibodies Doom Antigens<br/> Historical Highlights 32.2<br/> Convalescent Plasma: An Old Treatment for a New Disease<br/>32.9 The Immune System Can Malfunction<br/>33 The Microbe-Human Ecosystem<br/>Embrace Your Gut Flora<br/>33.1 Humans Are Holobionts<br/>33.2 The Microbiome Develops from Birth to Adulthood<br/>33.3 A Functional Core Microbiome Is Required for Host Homeostasis<br/>33.4 Many Diseases Have a Connection with Dysbiosis<br/>33.5 Microbiome Manipulation Can Be Therapeutic<br/>34 Infection and Pathogenicity<br/>The Unlikely Tale of Miasmas, Bras, and Masks<br/>34.1 The Process of Infection<br/>34.2 Transmission and Entry into the Host<br/> Historical Highlights 34.1<br/> The First Indications of Person-to-Person Spread of an Infectious Disease<br/>34.3 Surviving the Host Defenses<br/>34.4 Damage to the Host<br/>35 Epidemiology and Public Health Microbiology<br/>Protecting the Herd<br/>35.1 Epidemiology Is an Evidence-Based Science<br/> Historical Highlights 35.1<br/> John Snow, the First Epidemiologist<br/>35.2 Epidemiology Is Rooted in Well-Tested Methods<br/>35.3 Infectious Disease Is Revealed Through Patterns Within a Population<br/> Historical Highlights 35.2<br/> “Typhoid Mary”<br/>35.4 Infectious Diseases and Pathogens Are Emerging and Reemerging<br/>35.5 Healthcare Facilities Harbor Infectious Agents<br/>35.6 Coordinated Efforts Are Required to Prevent and Control Epidemics<br/> Historical Highlights 35.3<br/> The First Immunizations<br/>35.7 Bioterrorism Readiness Is an Integral Component of Public Health Microbiology<br/> Historical Highlights 35.4<br/> 1346—Early Biological Warfare Attack<br/>36 Clinical Microbiology and Immunology<br/>Ebola and Global Health Security<br/>36.1 The Clinical Microbiology Laboratory Detects Infectious Agents and Protects Its Workers<br/>36.2 Identification of Microorganisms from Specimens<br/>36.3 Immune Responses Can Be Exploited to Detect Infections<br/>37 Human Diseases Caused by Viruses and Prions<br/>Remembering HIV/AIDS<br/>37.1 Viruses Can Be Transmitted by Airborne Routes<br/>37.2 Arthropods Can Transmit Viral Diseases<br/>37.3 Direct Contact Diseases Can Be Caused by Viruses<br/>37.4 Food and Water Are Vehicles for Viral Diseases<br/> Historical Highlights 37.1<br/> A Brief History of Polio<br/>37.5 Zoonotic Diseases Arise from Human-Animal Interactions<br/>37.6 Prion Proteins Transmit Disease<br/>38 Human Diseases Caused by Bacteria<br/>The Plague Family Tree<br/>38.1 Bacteria Can Be Transmitted by Airborne Routes<br/>38.2 Arthropods Can Transmit Bacterial Diseases<br/>38.3 Direct Contact Diseases Can Be Caused by Bacteria<br/> Disease 38.1<br/> Syphilis and the Tuskegee Study<br/> Disease 38.2<br/> Biofilms<br/>38.4 Food and Water Are Vehicles for Bacterial Diseases<br/> Techniques & Applications 38.3<br/> Clostridial Toxins as Therapeutic Agents: Benefits of Nature’s Most Toxic Proteins<br/>38.5 Zoonotic Diseases Arise from Human-Animal Interactions<br/>38.6 Opportunistic Diseases Can Be Caused by Bacteria<br/>39 Human Diseases Caused by Fungi and Protists<br/>Mushrooms of Death<br/>39.1 Relatively Few Fungi and Protists Are Human Pathogens<br/>39.2 Fungi Can Be Transmitted by Airborne Routes<br/>39.3 Arthropods Can Transmit Protozoal Disease<br/> Disease 39.1<br/> A Brief History of Malaria<br/>39.4 Direct Contact Diseases Can Be Caused by Fungi and Protists<br/>39.5 Food and Water Are Vehicles of Protozoal Diseases<br/>39.6 Opportunistic Diseases Can Be Caused by Fungi and Protists<br/>40 Microbiology of Food<br/>The Art, Science, and Genetics of Brewing Beer<br/>40.1 Microbial Growth Can Cause Food Spoilage<br/>40.2 Environmental Factors Control Food Spoilage<br/>40.3 Food-Borne Disease Outbreaks<br/>40.4 Detection of Food-Borne Pathogens Requires Government-Industry Cooperation<br/>40.5 Microbiology of Fermented Foods: Beer, Cheese, and Much More<br/> Techniques & Applications 40.1<br/> Chocolate: The Sweet Side of Fermentation<br/>41 Biotechnology and Industrial Microbiology<br/>Where Are the New Antibiotics?<br/>41.1 Microbes Are the Source of Many Products of Industrial Importance<br/>41.2 Biofuel Production Is a Dynamic Field<br/>41.3 Growing Microbes in Industrial Settings Presents Challenges<br/>41.4 Agricultural Biotechnology Relies on a Plant Pathogen<br/>41.5 Some Microbes Are Products<br/>42 Applied Environmental Microbiology<br/>Deepwater Horizon Oil Consumed by Microbes<br/>42.1 Purification and Sanitary Analysis Ensure Safe Drinking Water<br/>42.2 Wastewater Treatment Maintains Human and Environmental Health<br/>42.3 Microbial Fuel Cells: Batteries Powered by Microbes<br/>42.4 Biodegradation and Bioremediation Harness Microbes to Clean the Environment<br/>Appendix 1 A Review of the Chemistry of Biological Molecules<br/>Appendix 2 Common Metabolic Pathways<br/>Appendix 3 Microorganism Pronunciation Guide<br/>Glossary<br/>Index<br/> |
| 520 ## - SUMMARY, ETC. | |
| Summary, etc | Prescott's Microbiology ISE<br/>The author team of Prescott’s Microbiology continues to provide a modern approach to microbiology using evolution as a framework. This new 12th edition integrates impactful new changes to include a fresh new design to engage students and important content updates including SARS-CoV-2 and COVID-19 which are prominently featured, taxonomic schemes that have been extensively revised, recent epidemiological data, and mRNA vaccines which just scrapes the surface of this new edition. |
| 650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM | |
| Topical term or geographic name as entry element | Microbiology. |
| 700 1# - ADDED ENTRY--PERSONAL NAME | |
| Personal name | Sandman, Kathleen M., |
| 700 1# - ADDED ENTRY--PERSONAL NAME | |
| Personal name | Wood, Dorothy H. |
| 700 1# - ADDED ENTRY--PERSONAL NAME | |
| Personal name | Prescott, Lansing M. |
| 856 40 - ELECTRONIC LOCATION AND ACCESS | |
| Uniform Resource Identifier | <a href="https://ebookcentral.proquest.com/lib/gla/detail.action?docID=7014724">https://ebookcentral.proquest.com/lib/gla/detail.action?docID=7014724</a> |
| 942 ## - ADDED ENTRY ELEMENTS (KOHA) | |
| Source of classification or shelving scheme | Dewey Decimal Classification |
| Koha item type | Project book |
| 100 1# - MAIN ENTRY--PERSONAL NAME | |
| Relator term | author. |
| 246 30 - VARYING FORM OF TITLE | |
| Title proper/short title | Microbiology. |
| 506 ## - RESTRICTIONS ON ACCESS NOTE | |
| Terms governing access | Access limited to subscribing institutions. |
| 700 1# - ADDED ENTRY--PERSONAL NAME | |
| Relator term | author. |
| 700 1# - ADDED ENTRY--PERSONAL NAME | |
| Fuller form of name | (Dorothy Henderson), |
| Relator term | author. |
| 700 1# - ADDED ENTRY--PERSONAL NAME | |
| Title of a work | Microbiology. |
| 776 08 - ADDITIONAL PHYSICAL FORM ENTRY | |
| Display text | Print version: |
| International Standard Book Number | 9781265123031. |
| 856 40 - ELECTRONIC LOCATION AND ACCESS | |
| Public note | Connect to resource |
| 907 ## - LOCAL DATA ELEMENT G, LDG (RLIN) | |
| a | .b41095959 |
| Withdrawn status | Lost status | Source of classification or shelving scheme | Damaged status | Not for loan | Collection code | Home library | Location | Date of Cataloging | Source of acquisition | Total Checkouts | Full call number | Barcode | Checked out | Date last seen | Date checked out | Price effective from | Koha item type |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Dewey Decimal Classification | Non-fiction | CUTN Central Library | CUTN Central Library | 13/08/2025 | DBT PG Project dt: 17.06.2025- Biotechnology | 1 | 579 WIL | 55507 | 10/11/2025 | 13/10/2025 | 13/10/2025 | 13/08/2025 | Project book |