Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Acknowledgements
- Chapter 1 The IPM paradigm: concepts, strategies and tactics
- Chapter 2 Economic impacts of IPM
- Chapter 3 Economic decision rules for IPM
- Chapter 4 Decision making and economic risk in IPM
- Chapter 5 IPM as applied ecology: the biological precepts
- Chapter 6 Population dynamics and species interactions
- Chapter 7 Sampling for detection, estimation and IPM decision making
- Chapter 8 Application of aerobiology to IPM
- Chapter 9 Introduction and augmentation of biological control agents
- Chapter 10 Crop diversification strategies for pest regulation in IPM systems
- Chapter 11 Manipulation of arthropod pathogens for IPM
- Chapter 12 Integrating conservation biological control into IPM systems
- Chapter 13 Barriers to adoption of biological control agents and biological pesticides
- Chapter 14 Integrating pesticides with biotic and biological control for arthropod pest management
- Chapter 15 Pesticide resistance management
- Chapter 16 Assessing environmental risks of pesticides
- Chapter 17 Assessing pesticide risks to humans: putting science into practice
- Chapter 18 Advances in breeding for host plant resistance
- Chapter 19 Resistance management to transgenic insecticidal plants
- Chapter 20 Role of biotechnology in sustainable agriculture
- Chapter 21 Use of pheromones in IPM
- Chapter 22 Insect endocrinology and hormone-based pest control products in IPM
- Chapter 23 Eradication: strategies and tactics
- Chapter 24 Insect management with physical methods in pre- and post-harvest situations
- Chapter 25 Cotton arthropod IPM
- Chapter 26 Citrus IPM
- Chapter 27 IPM in greenhouse vegetables and ornamentals
- Chapter 28 Vector and virus IPM for seed potato production
- Chapter 29 IPM in structural habitats
- Chapter 30 Fire ant IPM
- Chapter 31 Integrated vector management for malaria
- Chapter 32 Gypsy moth IPM
- Chapter 33 IPM for invasive species
- Chapter 34 IPM information technology
- Chapter 35 Private-sector roles in advancing IPM adoption
- Chapter 36 IPM: ideals and realities in developing countries
- Chapter 37 The USA National IPM Road Map
- Chapter 38 The role of assessment and evaluation in IPM implementation
- Chapter 39 From IPM to organic and sustainable agriculture
- Chapter 40 Future of IPM: a worldwide perspective
- Index
- References
Chapter 21 - Use of pheromones in IPM
Published online by Cambridge University Press: 01 September 2010
Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- Acknowledgements
- Chapter 1 The IPM paradigm: concepts, strategies and tactics
- Chapter 2 Economic impacts of IPM
- Chapter 3 Economic decision rules for IPM
- Chapter 4 Decision making and economic risk in IPM
- Chapter 5 IPM as applied ecology: the biological precepts
- Chapter 6 Population dynamics and species interactions
- Chapter 7 Sampling for detection, estimation and IPM decision making
- Chapter 8 Application of aerobiology to IPM
- Chapter 9 Introduction and augmentation of biological control agents
- Chapter 10 Crop diversification strategies for pest regulation in IPM systems
- Chapter 11 Manipulation of arthropod pathogens for IPM
- Chapter 12 Integrating conservation biological control into IPM systems
- Chapter 13 Barriers to adoption of biological control agents and biological pesticides
- Chapter 14 Integrating pesticides with biotic and biological control for arthropod pest management
- Chapter 15 Pesticide resistance management
- Chapter 16 Assessing environmental risks of pesticides
- Chapter 17 Assessing pesticide risks to humans: putting science into practice
- Chapter 18 Advances in breeding for host plant resistance
- Chapter 19 Resistance management to transgenic insecticidal plants
- Chapter 20 Role of biotechnology in sustainable agriculture
- Chapter 21 Use of pheromones in IPM
- Chapter 22 Insect endocrinology and hormone-based pest control products in IPM
- Chapter 23 Eradication: strategies and tactics
- Chapter 24 Insect management with physical methods in pre- and post-harvest situations
- Chapter 25 Cotton arthropod IPM
- Chapter 26 Citrus IPM
- Chapter 27 IPM in greenhouse vegetables and ornamentals
- Chapter 28 Vector and virus IPM for seed potato production
- Chapter 29 IPM in structural habitats
- Chapter 30 Fire ant IPM
- Chapter 31 Integrated vector management for malaria
- Chapter 32 Gypsy moth IPM
- Chapter 33 IPM for invasive species
- Chapter 34 IPM information technology
- Chapter 35 Private-sector roles in advancing IPM adoption
- Chapter 36 IPM: ideals and realities in developing countries
- Chapter 37 The USA National IPM Road Map
- Chapter 38 The role of assessment and evaluation in IPM implementation
- Chapter 39 From IPM to organic and sustainable agriculture
- Chapter 40 Future of IPM: a worldwide perspective
- Index
- References
Summary
During the past 68 years that have elapsed since the identification of the first insect pheromone (Butenandt, 1959) there has been a bourgeoning of basic and applied research that has resulted in an amazingly diverse and effective use of pheromones in IPM. Other behavior-modifying semiochemicals have had more limited success on a commercial level, although much research is continuing to try to find new ways to make such chemicals as host plant volatiles more useful in IPM settings as attractants or deterrents.
Although pheromones have established themselves in IPM systems, most end-users and even applied researchers do not realize how much work goes into identifying and optimizing pheromone blends so that they become highly species-specific and optimally attractive to the target species so that they can be used to the best effect. Research to determine the most effective pheromone blend compositions and dispenser dosages for monitoring and detection typically takes five to ten years to complete. Optimizing trap design targeting particular species can take several more years. Sometimes effective pheromones cannot be elucidated at all despite decades of intensive effort.
Delivery of effective commercial products presents another hurdle. For instance, applied pheromone researchers may spend years establishing that a particular mating disruption system is highly effective at disrupting mating and reducing crop damage after conducting experiments in which disruptant dispenser dosages and deployment densities have been varied.
- Type
- Chapter
- Information
- Integrated Pest ManagementConcepts, Tactics, Strategies and Case Studies, pp. 273 - 285Publisher: Cambridge University PressPrint publication year: 2008
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