Basic Laboratory Methods for Biotechnology and Basic Laboratory Calculations for Biotechnology Bundle
Autor Lisa Seidman, Cynthia J. Moore, Jeanette Moweryen Limba Engleză Paperback – 30 oct 2022
Fundamental laboratory skills are emphasized, and boxed content provides step by step laboratory method instructions for ease of reference at any point in the students’ progress. Worked through examples and practice problems and solutions assist student comprehension. Coverage includes safety practices and instructions on using common laboratory instruments.
Key Features:
- Provides a valuable reference for laboratory professionals at all stages of their careers.
- Focuses on basic principles and methods to provide students with the knowledge needed to begin a career in the Biotechnology industry.
- Describes fundamental laboratory skills.
- Includes laboratory scenario-based questions that require students to write or discuss their answers to ensure they have mastered the chapter content.
- Updates reflect recent innovations and regulatory requirements to ensure students stay up to date.
- Tables, a detailed glossary, practice problems and solutions, case studies and anecdotes provide students with the tools needed to master the content.
To succeed in the lab, it is crucial to be comfortable with the math calculations that are part of everyday work. This accessible introduction to common laboratory techniques focuses on the basics, helping even readers with good math skills to practice the most frequently encountered types of problems.
Basic Laboratory Calculations for Biotechnology, Second Edition discusses very common laboratory problems, all applied to real situations. It explores multiple strategies for solving problems for a better understanding of the underlying math. Primarily organized around laboratory applications, the book begins with more general topics and moves into more specific biotechnology laboratory techniques at the end.
This book features hundreds of practice problems, all with solutions and many with boxed, complete explanations; plus hundreds of "story problems" relating to real situations in the lab. Additional features include:
- Discusses common laboratory problems with all material applied to real situations
- Presents multiple strategies for solving problems help students to better understand the underlying math
- Provides hundreds of practice problems and their solutions
- Enables students to complete the material in a self-paced course structure with little teacher assistance
- Includes hundreds of "story problems"that relate to real situations encountered in the laboratory
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Specificații
ISBN-13: 9781032366241
ISBN-10: 1032366249
Pagini: 1788
Ilustrații: 2210
Dimensiuni: 156 x 234 mm
Greutate: 3.3 kg
Ediția:1
Editura: CRC Press
Colecția CRC Press
ISBN-10: 1032366249
Pagini: 1788
Ilustrații: 2210
Dimensiuni: 156 x 234 mm
Greutate: 3.3 kg
Ediția:1
Editura: CRC Press
Colecția CRC Press
Cuprins
UNIT I Biotechnology is the Transformation of Knowledge into Useful Products. 1. Techniques to Manipulate DNA: The Root of the Biotechnology Industry. 2. The Biotechnology Industry Branches Out. 3. The Business of Biotechnology: The Transformation of Knowledge into Products. UNIT II Introduction to Quality in Biotechnology Workplaces. Chapter 4. An Overview of Quality Principles in Biotechnology. 5. Quality in Research Laboratories. 6. Documentation: The Foundation of Quality. UNIT III Safety in the Laboratory. 7. Introduction to a Safe Workplace. 8. Working Safely in the Laboratory: General Considerations and Physical Hazards. 9. Working Safely with Chemicals. 10. Working Safely with Biological Materials. UNIT IV Math in the Biotechnology Laboratory: An Overview. 11. Basic Math Techniques. 12. Proportional Relationships. 13. Relationships and Graphing. 14. Descriptions of Data: Descriptive Statistics. UNIT V Obtaining Reproducible Laboratory Measurements. 16. Introduction to Instrumental Methods and Electricity. 17. The Measurement of Weight. 18. The Measurement of Volume. 19. The Measurement of Temperature. 20. The Measurement of pH, Selected Ions, and Conductivity. 21. Measurements Involving Light – Part A: Basic Principles and Instrumentation. UNIT VI Laboratory Solutions. 22. Preparation of Laboratory Solutions – Part A: Concentration Expressions and Calculations. 23. Preparation of Laboratory Solutions – Part B: Basic Procedures and Buffers. 24. Solutions: Associated Procedures and Information. 25. Laboratory Solutions to Support the Activity of Biological Macromolecules. UNIT VII Quality Assays and Tests. 26. Introduction to Quality Laboratory Tests and Assays. 27. Achieving Reproducible Results with Polymerase Chain Reaction Assays. 28. Measurements Involving Light – Part B: Assays. 29. Achieving Reproducible Immunoassay Results. UNIT VIII Cell Culture and Reproducibility. 30. Introduction to Quality Practices for Cell Culture. 31. Culture Media for Intact Cells. UNIT IX Basic Separation Methods. 32. Introduction to Filtration. 33. Introduction to Centrifugation. 34. Introduction to Bioseparations.UNIT X Biotechnology and Regulatory Affairs. 35. Biotechnology and the Regulation of Medical and Food Products. 36. The Lifecycles and Regulation of Pharmaceutical Products. 37. The Lifecycles and Regulation of Biopharmaceutical and Regenerative Medicine Products. 38. Quality Systems in a Regulated Production Facility. Appendix: Answers to Practice Problems. Acronyms. Glossary Terms.
UNIT I Biotechnology is the Transformation of Knowledge into Useful Products. 1. Techniques to Manipulate DNA: The Root of the Biotechnology Industry. 2. The Biotechnology Industry Branches Out. 3. The Business of Biotechnology: The Transformation of Knowledge into Products. UNIT II Introduction to Quality in Biotechnology Workplaces. Chapter 4. An Overview of Quality Principles in Biotechnology. 5. Quality in Research Laboratories. 6. Documentation: The Foundation of Quality. UNIT III Safety in the Laboratory. 7. Introduction to a Safe Workplace. 8. Working Safely in the Laboratory: General Considerations and Physical Hazards. 9. Working Safely with Chemicals. 10. Working Safely with Biological Materials. UNIT IV Math in the Biotechnology Laboratory: An Overview. 11. Basic Math Techniques. 12. Proportional Relationships. 13. Relationships and Graphing. 14. Descriptions of Data: Descriptive Statistics. UNIT V Obtaining Reproducible Laboratory Measurements. 16. Introduction to Instrumental Methods and Electricity. 17. The Measurement of Weight. 18. The Measurement of Volume. 19. The Measurement of Temperature. 20. The Measurement of pH, Selected Ions, and Conductivity. 21. Measurements Involving Light – Part A: Basic Principles and Instrumentation. UNIT VI Laboratory Solutions. 22. Preparation of Laboratory Solutions – Part A: Concentration Expressions and Calculations. 23. Preparation of Laboratory Solutions – Part B: Basic Procedures and Buffers. 24. Solutions: Associated Procedures and Information. 25. Laboratory Solutions to Support the Activity of Biological Macromolecules. UNIT VII Quality Assays and Tests. 26. Introduction to Quality Laboratory Tests and Assays. 27. Achieving Reproducible Results with Polymerase Chain Reaction Assays. 28. Measurements Involving Light – Part B: Assays. 29. Achieving Reproducible Immunoassay Results. UNIT VIII Cell Culture and Reproducibility. 30. Introduction to Quality Practices for Cell Culture. 31. Culture Media for Intact Cells. UNIT IX Basic Separation Methods. 32. Introduction to Filtration. 33. Introduction to Centrifugation. 34. Introduction to Bioseparations.UNIT X Biotechnology and Regulatory Affairs. 35. Biotechnology and the Regulation of Medical and Food Products. 36. The Lifecycles and Regulation of Pharmaceutical Products. 37. The Lifecycles and Regulation of Biopharmaceutical and Regenerative Medicine Products. 38. Quality Systems in a Regulated Production Facility. Appendix: Answers to Practice Problems. Acronyms. Glossary Terms.
UNIT I Biotechnology is the Transformation of Knowledge into Useful Products. 1. Techniques to Manipulate DNA: The Root of the Biotechnology Industry. 2. The Biotechnology Industry Branches Out. 3. The Business of Biotechnology: The Transformation of Knowledge into Products. UNIT II Introduction to Quality in Biotechnology Workplaces. Chapter 4. An Overview of Quality Principles in Biotechnology. 5. Quality in Research Laboratories. 6. Documentation: The Foundation of Quality. UNIT III Safety in the Laboratory. 7. Introduction to a Safe Workplace. 8. Working Safely in the Laboratory: General Considerations and Physical Hazards. 9. Working Safely with Chemicals. 10. Working Safely with Biological Materials. UNIT IV Math in the Biotechnology Laboratory: An Overview. 11. Basic Math Techniques. 12. Proportional Relationships. 13. Relationships and Graphing. 14. Descriptions of Data: Descriptive Statistics. UNIT V Obtaining Reproducible Laboratory Measurements. 16. Introduction to Instrumental Methods and Electricity. 17. The Measurement of Weight. 18. The Measurement of Volume. 19. The Measurement of Temperature. 20. The Measurement of pH, Selected Ions, and Conductivity. 21. Measurements Involving Light – Part A: Basic Principles and Instrumentation. UNIT VI Laboratory Solutions. 22. Preparation of Laboratory Solutions – Part A: Concentration Expressions and Calculations. 23. Preparation of Laboratory Solutions – Part B: Basic Procedures and Buffers. 24. Solutions: Associated Procedures and Information. 25. Laboratory Solutions to Support the Activity of Biological Macromolecules. UNIT VII Quality Assays and Tests. 26. Introduction to Quality Laboratory Tests and Assays. 27. Achieving Reproducible Results with Polymerase Chain Reaction Assays. 28. Measurements Involving Light – Part B: Assays. 29. Achieving Reproducible Immunoassay Results. UNIT VIII Cell Culture and Reproducibility. 30. Introduction to Quality Practices for Cell Culture. 31. Culture Media for Intact Cells. UNIT IX Basic Separation Methods. 32. Introduction to Filtration. 33. Introduction to Centrifugation. 34. Introduction to Bioseparations.UNIT X Biotechnology and Regulatory Affairs. 35. Biotechnology and the Regulation of Medical and Food Products. 36. The Lifecycles and Regulation of Pharmaceutical Products. 37. The Lifecycles and Regulation of Biopharmaceutical and Regenerative Medicine Products. 38. Quality Systems in a Regulated Production Facility. Appendix: Answers to Practice Problems. Acronyms. Glossary Terms.
Notă biografică
Lisa Seidman obtained her Ph.D. from the University of Wisconsin and has taught for more than thirty years in the Biotechnology Laboratory Technician Program at Madison Area Technical College. She is presently serving as Emeritus Faculty at the college.
Cynthia Moore received her Ph.D. in Microbiology from Temple University School of Medicine. She has taught for more than twenty years in the School of Biological Sciences at Illinois State University, where she currently serves as Emeritus Faculty.
Jeanette Mowery obtained her Ph.D. in Biomedical Science from the University of Texas Health Science Center-Houston. She has taught for more than 20 years in the Biotechnology Laboratory Technician Program at Madison Area Technical College, and is currently serving as Emeritus Faculty at the college.
Cynthia Moore received her Ph.D. in Microbiology from Temple University School of Medicine. She has taught for more than twenty years in the School of Biological Sciences at Illinois State University, where she currently serves as Emeritus Faculty.
Jeanette Mowery obtained her Ph.D. in Biomedical Science from the University of Texas Health Science Center-Houston. She has taught for more than 20 years in the Biotechnology Laboratory Technician Program at Madison Area Technical College, and is currently serving as Emeritus Faculty at the college.
Descriere
This versatile textbook provides students with a solid foundation to pursue employment in the biotech industry and can later serve as a practical reference to ensure success at each stage in their career. To succeed in the lab, it is crucial to be comfortable with the math calculations that are part of everyday work.