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Editorial

Sterile Insect Technique (SIT) and Its Applications

by
Kostas Bourtzis
* and
Marc J. B. Vreysen
*
Insect Pest Control Laboratory, Joint FAO/IAEA Centre of Nuclear Techniques in Food and Agriculture, A-2444 Seibersdorf, Austria
*
Authors to whom correspondence should be addressed.
Insects 2021, 12(7), 638; https://doi.org/10.3390/insects12070638
Submission received: 8 July 2021 / Accepted: 11 July 2021 / Published: 13 July 2021
(This article belongs to the Special Issue Sterile Insect Technique (SIT) and Its Applications)
Versions Notes

Abstract

:

Simple Summary

Insects represent the most speciose and abundant group of animals on this planet. Most species are beneficial, however, a small number of them are major plant pests or vectors of major pathogens in livestock and humans. Insecticides have been used for decades as the main weapon for the population control of insect pests. However, concerns about human health and the environment as well as the increased prevalence of insecticide resistance have called for more environment-friendly and sustainable insect pest control approaches such as the sterile insect technique (SIT).

Abstract

Although most insect species have a beneficial role in the ecosystems, some of them represent major plant pests and disease vectors for livestock and humans. During the last six–seven decades, the sterile insect technique (SIT) has been used as part of area-wide integrated pest management strategies to suppress, contain, locally eradicate or prevent the (re)invasion of insect pest populations and disease vectors worldwide. This Special Issue on “Sterile insect technique (SIT) and its applications”, which consists of 27 manuscripts (7 reviews and 20 original research articles), provides an update on the research and development efforts in this area. The manuscripts report on all the different components of the SIT package including mass-rearing, development of genetic sexing strains, irradiation, quality control as well as field trials.

1. Introduction

Insects epitomize the most evolutionary successful animal group on Earth. They have adapted almost everywhere on our planet to diverse ecological conditions. The majority of insect species play an important and beneficial role in the ecosystems. However, some of them represent a significant threat for agricultural production as well as for animal and human health. For decades, application of broad-spectrum insecticides has been the main tool for the management of insect pest populations and disease vectors. The continuous and irrational use of these chemicals has resulted in widespread insecticide resistance while their negative impact on human health, food chain and the environment has been documented beyond any doubt. There is an urgent need for environment-friendly, species-specific, and sustainable approaches, such as the sterile insect technique (SIT) for the population control of insect species and disease vectors [1].
The concept of the SIT was conceived by Edward F. Knipling, and it was first used for the population control of the New World screwworm, Cochliomyia hominivorax in the 1950s [2]. Since then, it has been successfully used as a component of area-wide integrated pest management (AW-IPM) approaches [3], to suppress, contain, prevent the (re)introduction and even locally eradicate populations of insect pests and disease vectors [1,4]. This Special Issue on “Sterile insect technique (SIT) and its applications” presents recent progress in this area as well as the challenges SIT faces from the developmental phase until its implementation in the field. The Special Issue consists of 27 manuscripts (7 reviews and 20 original research articles) covering a wide range of components of the SIT package including mass-rearing, development of genetic sexing strains, irradiation, quality control as well as small-scale field trials and large-scale, operational population suppression programs (https://www.mdpi.com/journal/insects/special_issues/mr_sit accessed on 8 July 2021). The manuscripts present results and achievements from work focusing on all main groups of SIT target species such as plant pests (fruit flies, lepidoptera), livestock pests (tsetse flies and sheep blow fly), and human disease vectors (mosquitoes), and some unusual groups such as Hemiptera.

2. Fruit Flies

The development of robust and cost-effective (mass-)rearing systems is a prerequisite for the development and implementation of the SIT. Sassù and colleagues (2019) report on the development and comparative evaluation of a wax panel and a netted oviposition system as egg collection systems for the spotted wing drosophila, Drosophila suzukii [5]. The results presented clearly show that the wax panel system is more practical, less laborious and produces significantly more and higher quality eggs than the netted oviposition system. Pascacio-Villafán and colleagues (2020) used different ingredients as gelling agents in yeast-reduced gel diets indicating that only the ones with agar and carrageenan are cheaper and produce more and better-quality Mexican fruit flies Anastrepha ludens compared to the diet currently used in the Moscafrut mass-rearing facility [6]. In addition, the gel-carrageenan diet produces suitable larvae as hosts for the rearing of the parasitoid Diachasmimorpha longicaudata.
Pascacio-Villafán and colleagues (2021) also tested different pupation substrates and substrate volumes for the Mediterranean fruit fly Ceratitis capitata VIENNA 8 genetic sexing strain (GSS) that is currently used by almost all operational SIT programs against this major agricultural pest worldwide [7]. They concluded that cellulose III at low volumes is the best pupation substrate, with respect to productivity, quality and cost-effectiveness. Mastrangelo and colleagues (2021) report on an improved rearing protocol for the South American fruit fly Anastrepha fraterculus (Vacaria strain), including a novel larval diet in which agar has been replaced by carrageenan [8]. The new rearing protocol was efficient and cost-effective producing insects of high quality that can be used for SIT applications. Importantly, after two years of using this novel rearing protocol and larval diet, no evidence of sexual isolation has been observed between mass-produced insects and the wild target population.
Although SIT applications for fruit flies can be successfully implemented by releasing both sterile males and sterile females, it has been shown that the efficiency and cost-effectiveness can be increased significantly if only sterile males are released [9,10]. Ramirez and colleagues (2021) present a new GSS for A. ludens, namely GUA10 that is based on the black pupae (bp) gene [11]. Comparative analysis showed that the A. ludens GUA10 GSS exhibits better rearing efficiency, genetic stability and overall quality than the previously developed A. ludens TAP7 GSS. In addition, Nguyen and colleagues (2021) discuss how currently available knowledge about single point mutations of the vinegar fly Drosophila melanogaster genes, which are known to result to temperature sensitive phenotypes, can be exploited in order to induce similar mutations in the orthologous genes of insect pests and disease vectors for the construction of GSS in support of SIT and other insect pest control programs [12].
Several studies have shown that high quality sterile flies for SIT applications can be produced when the insects are irradiated under hypoxic (low oxygen) conditions. Giustina and colleagues (2020) reported that males of two A. fraterculus strains (a bisexual strain and a GSS) require a dose of 74 Gy administered under hypoxia to induce 99% sterility in females while an irradiation dose between 80–90 Gy can induce complete sterility [13]. On the other hand, females can be fully sterilized with an irradiation dose of 50 Gy or above.
The importance of proper quality control and evaluation of every step in an SIT program, particularly if it is at an operational level, is also highlighted in the manuscript by Pla and colleagues (2021) [14]. The authors review the significant achievements of the SIT population suppression program carried out against C. capitata by the Department of Agriculture and the TRAGSA company in Valencia, Spain. In 2007, the SIT was incorporated in an AW-IPM program to manage C. capitata populations with the main goal to drastically reduce insecticide use and to protect the production and export industry of citrus and other fresh fruits in the region. The results of the program are impressive: a >90% reduction in insecticide use and significant increase in the export of citrus and fresh fruits for the Valencia community.

3. Lepidoptera

Lepidoptera are, in addition to fruit flies, major agricultural pests and their populations can be very efficiently managed by AW-IPM programs that include an SIT component. Marec and Vreysen (2020) [15] discuss the characteristic cytogenetic features of Lepidoptera as well as their high resistance to ionizing radiation. The latter property has resulted in the development of the inherited sterility (IS) method, an SIT-derived technology, which is currently used to successfully suppress populations of several lepidopteran pest species. In addition, the authors report on the quality control analysis of (mass-) reared and released insects, which is the key for successful SIT/IS applications, and they also discuss how recent developments in genetics and genomics may facilitate the development of genetic sexing strains.
No SIT or any other insect pest control method can be applied and be successful if it is not socially acceptable. Paterson and colleagues (2020) [16] present a study which indicates the positive perception of a local community in Hastings, New Zealand in respect to hosting insect traps in their properties and to applying SIT against the codling moth Cydia pomonella. In an interesting field trial, Horner and colleagues (2020a) [17] report that an AW-IPM project in New Zealand, which was based on the initial reduction of target pest populations by mating disruption and insecticides followed by sterile male-only releases, suppressed codling moth populations with 67% to 99%. In addition, Horner and colleagues (2020b) [18] show that codling moth populations that remain at high population densities in unmanaged peri-urban sites pose a significant risk of immigration into treated orchards. They suggest that these populations need to be reduced by SIT applications in the frame of an AW-IPM suppression program. Esch and colleagues (2021) [19] showed that sterile codling moths can be successfully released by small uncrewed aircraft systems (UASs). The data presented clearly indicate that UAS-based releases achieved higher recapture rates as compared with ground releases and are much cheaper to operate than the commonly used fixed wing aircraft for the release of sterile moths.
Recently, a project has been initiated in Arica, Chile aiming at the development and implementation of the SIT, as part of an AW-IPM approach, to suppress populations of the European grapevine moth Lobesia botrana. Simmons and colleagues (2021) [20] review the activities of this program describing the advances (rearing, irradiation, packaging, transport, release and monitoring) as well as the challenges to achieve releases of high-quality sterile males at adequate overflooding ratios in non-isolated urban areas.

4. Hemiptera

Hemiptera are an unusual target insect group for the SIT, in view that all development stages and potential release stages can cause damage to crops. Despite this, efforts have been made to assess whether populations of some hemipteran pest species can be targeted by the SIT, and the brown marmorated stink bug Halyomorpha halys has been considered as a potential candidate by some researchers. Suckling and colleagues (2020a) [21] present a novel live (or lethal) trap for this insect pest species that is a cheaper and more efficient alternative to the currently available ones. These traps could be useful for AW-IPM approaches with an SIT component. In a separate study, Suckling and colleagues (2020b) [22] report that an irradiation dose of 16 Gy did not affect the mating competitiveness and competency of H. halys males and could be considered a suitable dose in SIT-based population suppression programs. The authors also note that dosimetry is important and follow-up studies need to be performed in order to explain the different sterility levels obtained by the same irradiation dose in different facilities. The authors further discuss the potential of collecting overwintering males from the field using the aggregation pheromone, and then sterilized and released them as an alternative to the more conventional pathway which is based on the (mass-)rearing in a facility, irradiation and then release of sterile insects. However, this “alternative” procedure may be challenging both at the application and regulatory level. Interestingly, and similar to the abovementioned study on H. halys, Horrocks and colleagues (2020) [23] show that the application of an irradiation dose of 16 Gy or higher could sterilize male green vegetable bug Nezara viridula, another hemipteran species, by >99%, while females required a dose of 28 Gy to become fully sterile.

5. Livestock Pests

The SIT has been successfully used for the suppression, and even the local eradication, of tsetse populations transmitting African trypanosomes causing sleeping sickness in humans and nagana in animals [4]. Mating performance of irradiated male insects is one of the key factors that need to be evaluated before the implementation of SIT releases. De Beer and colleagues (2020) [24] report that irradiation of Glossina austeni males from a 37 year-old colony as adults or late stage pupae to obtain ca. 99% sterility did not affect their mating performance, and it was concluded that these sterile males are suitable for SIT applications as shown in laboratory and semi-field experiments.
The SIT has also been proposed as a tool to control populations of another major livestock pest species, the Australian sheep blow fly Lucilia cuprina. Yan and colleagues (2020) [25] report on the development of a transgenic embryonic sexing system (TESS) that results in the elimination of females at the embryonic stage in the absence of tetracycline from the diet, which could potentially be used for male-only releases if regulatory approval is granted.

6. Mosquitoes

The SIT has been very successful to manage populations of plant and livestock pests worldwide [1,4]. More recently, the SIT has been considered as a tool to suppress mosquito species transmitting major human pathogens, such as the yellow fever mosquito Aedes aegypti and the Asian tiger mosquito Ae. albopictus, using a phased conditional approach [26,27]. Oliva and colleagues (2021) [28] present a roadmap and good practice framework for the design, implementation, and evaluation of pilot field trials aiming at the suppression of Ae. aegypti and Ae. albopictus populations using the SIT. This pathway is addressed not only to scientists but also to non-specialists including stakeholders, implementers, and decision-makers. Gouagna and colleagues (2020) [29] report on the SIT feasibility program developed and implemented in La Réunion island against Ae. albopictus and review all activities, from the laboratory to the field, carried out during the last ten years including a public awareness campaign and regulatory validation. As public acceptance and support is an important parameter for the successful implementation of an SIT program, Stefopoulou and colleagues (2021) [30] used a KAP (knowledge, attitude, practices) survey and carried out a door-to-door campaign as a prerelease action to inform the Vravrona community, Attica, Greece about an upcoming SIT trial to suppress an Ae. albopictus population in that area. The residents were very positive and supportive of the SIT project, and this was further confirmed by the reduction of the target mosquito population before the initiation of the sterile male releases, most likely due to the removal of mosquito habitats from residents’ yards.
Availability of entomological baseline data, ideally over a period of two years prior to an intervention, is also one of the prerequisites for SIT applications. Marina and colleagues (2021) [31] monitored the population dynamics of Ae. aegypti and Ae. albopictus for two years (2016–2018) in two rural villages in Chiapas, Mexico. Data collected were carefully evaluated and taken into consideration in the design of a small-scale SIT field trial against Ae. aegypti. Using mosquitoes from the Chiapas region, Bond and colleagues (2021) [32] investigated the effects of irradiation on the mating competitiveness of Ae. aegypti and Ae. albopictus males under both laboratory and field-cage conditions. The results clearly indicate that the produced sterile male Ae. aegypti and Ae. albopictus maintained their competitiveness and when treated with an irradiation dose of 50 and 40 Gy, respectively, they induced up to 88% sterility under field-cage conditions.
During the last years there has been an increase in developing and testing the SIT in the field against Ae. aegypti and Ae. albopictus populations in different parts of the world. Tur and colleagues (2021) [33] report on a recent initiative of the Agriculture Department of the Valencian Region, Spain to develop and implement a small-scale SIT field trial against the invasive mosquito species, Ae. albopictus. The authors present the current operating procedures and quality control parameters of the established medium-scale rearing facility, which has produced over 15 million irradiated sterile males for release during the last two years (2018–2020) with a minimal average female contamination of 0.17%.
Gato and colleagues (2021) [34] present the impressive results of an SIT field trial against Ae. aegypti in two sub-urban areas of Havana, Cuba. During a period of 20 weeks, more than 1.2 million sterile males were released over an inhabited target area of about 50 ha. The sterile males were highly competitive, induced high levels of sterility and managed to fully suppress the target population as assessed by the ovitrap index and the mean number of eggs per trap. It is worth noting that during the last three weeks of the intervention, there were no eggs in the ovitraps of the treatment area.

7. Insect Pest Control Laboratory

Last but not least, the review article by Vreysen and colleagues (2021b) [35] on “The FAO/IAEA Insect Pest Control Laboratory: ten years (2010–2020) of research and development, achievements and challenges in support of the sterile insect technique” summarizes the catalytic progress which has been achieved on the development and refinement of the SIT of an important number of insect pests and disease vectors (fruit flies, lepidoptera, tsetse flies and mosquitoes) through the systematic and problem-solving R&D work carried out at the Insect Pest Control Laboratory. This R&D has significantly improved the efficiency and cost-effectiveness of the SIT towards the population management of insect pests of agricultural, veterinary and human health importance. In addition, it has resulted to the expansion of the SIT target species by including species such as An. fraterculus, D. suzukii and Aedes mosquitoes. The review also presents the collaborative research efforts carried out in the frame of Coordinated Research Projects (CRP), how the knowledge is transferred to FAO and IAEA Member States through Technical Cooperation Projects (TCP) as well as the major challenges faced.

8. Conclusions

The SIT has constantly proven its capacity to suppress, contain, prevent (re)introduction or even locally eradicate populations of selected key insect plant and livestock pests. However, there is also a continuous need to further refine and improve the efficiency as well as the cost-effectiveness. Several of the studies presented in the present Special Issue on “The sterile insect technique (SIT) and its applications” show that the (mass-)rearing, sex separation, irradiation, handling, packaging, and release process can be further refined including the quality control analysis of both the product and the process. In addition, it has been shown there is significant room for the expansion of the SIT to new target species of plant pests such as D. suzukii and even some potential hemipteran species.
During the last years, there has also been an increasing demand to develop and apply the SIT against mosquito vectors of human diseases such as Ae. aegypti and Ae. albopictus. Major advances have been made with a wide range of components of the SIT package, and this is reflected in the fact that several small-scale field trials are being carried out in several parts of the world against these two mosquito species with very encouraging results.
The major challenges for the further enhancement and deployment of SIT is the automation of as many steps as possible, the (faster) development of stable GSSs and the careful design and implementation of small-scale field trials using a phased conditional approach prior to any large-scale deployment. In all cases, the most important factor is the strong political will and commitment during all phases of an AW-IPM project with an SIT component.

Author Contributions

Conceptualization, K.B. and M.J.B.V.; writing—review and editing, K.B. and M.J.B.V. All authors have read and agreed to the published version of the manuscript.

Funding

Most of the research at the IPCL was carried out using regular budget contributions of the IAEA/FAO member states to the Insect Pest Control Subprogram. Some research at the IPCL benefitted from extrabudgetary contributions of the US, UK, France, Pakistan, EU, Austria, the Netherlands, and Iran. Some of the field work was co-funded by the IAEA Department of Technical Cooperation.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare that there is no conflict of interest.

References

  1. Dyck, V.A.; Hendrichs, J.; Robinson, A.S. (Eds.) Sterile Insect Technique: Principles and Practice in Area-Wide Integrated Pest Management, 2nd ed.; CRC Press: Boca Raton, FL, USA, 2021; ISBN 978-1-00-303557-2. [Google Scholar]
  2. Knipling, E.F. Sterile-male method of population control. Science 1959, 130, 902–904. [Google Scholar] [CrossRef] [PubMed]
  3. Klassen, W.; Vreysen, M.J.B. Area-wide integrated pest management and the sterile insect technique. In The Sterile Insect Technique: Principles and Practice in Area-Wide Integrated Pest Management; Dyck, V.A., Hendrichs, J., Robinson, A.S., Eds.; CRC Press: Boca Raton, FL, USA, 2021; pp. 75–112. ISBN 978-1-00-303557-2. [Google Scholar]
  4. Vreysen, M.; Seck, M.; Sall, B.; Mbaye, A.; Bassène, M.; Fall, A.; Lo, M.; Bouyer, J. Area-wide integrated management of a Glossina palpalis gambiensis population from the Niayes area of Senegal: A review of operational research in support of a phased conditional approach. In Area-Wide Integrated Pest Management: Development and Field Application; Hendrichs, J., Pereira, R., Vreysen, M.J., Eds.; CRC Press: Boca Raton, FL, USA, 2021; pp. 275–303. [Google Scholar]
  5. Sassù, F.; Nikolouli, K.; Caravantes, S.; Taret, G.; Pereira, R.; Vreysen, M.J.B.; Stauffer, C.; Cáceres, C. Mass-Rearing of Drosophila suzukii for Sterile Insect Technique Application: Evaluation of Two Oviposition Systems. Insects 2019, 10, 448. [Google Scholar] [CrossRef] [Green Version]
  6. Pascacio-Villafán, C.; Guillén, L.; Aluja, M. Agar and Carrageenan as Cost-Effective Gelling Agents in Yeast-Reduced Artificial Diets for Mass-Rearing Fruit Flies and Their Parasitoids. Insects 2020, 11, 131. [Google Scholar] [CrossRef] [Green Version]
  7. Pascacio-Villafán, C.; Quintero-Fong, L.; Guillén, L.; Rivera-Ciprian, J.P.; Aguilar, R.; Aluja, M. Pupation Substrate Type and Volume Affect Pupation, Quality Parameters and Production Costs of a Reproductive Colony of Ceratitis capitata (Diptera: Tephritidae) VIENNA 8 Genetic Sexing Strain. Insects 2021, 12, 337. [Google Scholar] [CrossRef]
  8. Mastrangelo, T.; Kovaleski, A.; Maset, B.; de Lourdes Zamboni Costa, M.; Barros, C.; Lopes, L.A.; Carlos Caceres, C. Improvement of the Mass-Rearing Protocols for the South American Fruit Fly for Application of the Sterile Insect Technique. Insects 2021, 12, 622. [Google Scholar] [CrossRef]
  9. Rendón, P.; McInnis, D.; Lance, D.; Stewart, J. Medfly (Diptera: Tephritidae) Genetic sexing: Large-scale field comparison of males-only and bisexual sterile fly releases in Guatemala. J. Econ. Entomol. 2004, 97, 1547–1553. [Google Scholar] [CrossRef]
  10. Franz, G.; Bourtzis, K.; Caceres, C. Practical and operational genetic sexing systems based on classical genetic approaches in fruit flies, an example for other species amenable to large-scale rearing for the sterile insect technique. In Sterile Insect Technique: Principles and Practice in Area-Wide Integrated Pest Management, 2nd ed.; Dyck, V.A., Hendrichs, J., Robinson, A.S., Eds.; CRC Press: Boca Raton, FL, USA, 2021; pp. 575–604. [Google Scholar]
  11. Ramírez-Santos, E.; Rendon, P.; Gouvi, G.; Zacharopoulou, A.; Bourtzis, K.; Cáceres, C.; Bloem, K. A Novel Genetic Sexing Strain of Anastrepha Ludens for Cost-Effective Sterile Insect Technique Applications: Improved Genetic Stability and Rearing Efficiency. Insects 2021, 12, 499. [Google Scholar] [CrossRef]
  12. Nguyen, T.N.M.; Choo, A.; Baxter, S.W. Lessons from Drosophila: Engineering Genetic Sexing Strains with Temperature-Sensitive Lethality for Sterile Insect Technique Applications. Insects 2021, 12, 243. [Google Scholar] [CrossRef]
  13. Giustina, P.D.; Mastrangelo, T.; Ahmad, S.; Mascarin, G.; Caceres, C. Determining the Sterilization Doses under Hypoxia for the Novel Black Pupae Genetic Sexing Strain of Anastrepha fraterculus (Diptera, Tephritidae). Insects 2021, 12, 308. [Google Scholar] [CrossRef]
  14. Plá, I.; García de Oteyza, J.; Tur, C.; Martínez, M.Á.; Laurín, M.C.; Alonso, E.; Martínez, M.; Martín, Á.; Sanchis, R.; Navarro, M.C.; et al. Sterile Insect Technique Programme against Mediterranean Fruit Fly in the Valencian Community (Spain). Insects 2021, 12, 415. [Google Scholar] [CrossRef] [PubMed]
  15. Marec, F.; Vreysen, M.J.B. Advances and Challenges of Using the Sterile Insect Technique for the Management of Pest Lepidoptera. Insects 2019, 10, 371. [Google Scholar] [CrossRef] [Green Version]
  16. Paterson, G.; Perry, G.L.W.; Walker, J.T.S.; Suckling, D.M. Peri-Urban Community Attitudes towards Codling Moth Trapping and Suppression Using the Sterile Insect Technique in New Zealand. Insects 2019, 10, 335. [Google Scholar] [CrossRef] [Green Version]
  17. Horner, R.M.; Lo, P.L.; Rogers, D.J.; Walker, J.T.S.; Suckling, D.M. Combined Effects of Mating Disruption, Insecticides, and the Sterile Insect Technique on Cydia pomonella in New Zealand. Insects 2020, 11, 837. [Google Scholar] [CrossRef]
  18. Horner, R.; Paterson, G.; Walker, J.T.S.; Perry, G.L.W.; Jaksons, R.; Suckling, D.M. Will Peri-Urban Cydia pomonella (Lepidoptera: Tortricidae) Challenge Local Eradication? Insects 2020, 11, 207. [Google Scholar] [CrossRef] [Green Version]
  19. Esch, E.D.; Horner, R.M.; Krompetz, D.C.; Moses-Gonzales, N.; Tesche, M.R.; Suckling, D.M. Operational Parameters for the Aerial Release of Sterile Codling Moths Using an Uncrewed Aircraft System. Insects 2021, 12, 159. [Google Scholar] [CrossRef] [PubMed]
  20. Simmons, G.S.; Salazar Sepulveda, M.C.; Fuentes Barrios, E.A.; Idalsoaga Villegas, M.; Medina Jimenez, R.E.; Garrido Jerez, A.R.; Henderson, R.; Donoso Riffo, H. Development of Sterile Insect Technique for Control of the European Grapevine Moth, Lobesia botrana, in Urban Areas of Chile. Insects 2021, 12, 378. [Google Scholar] [CrossRef]
  21. Suckling, D.M.; Levy, M.C.; Roselli, G.; Mazzoni, V.; Ioriatti, C.; Deromedi, M.; Cristofaro, M.; Anfora, G. Live Traps for Adult Brown Marmorated Stink Bugs. Insects 2019, 10, 376. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Suckling, D.M.; Cristofaro, M.; Roselli, G.; Levy, M.C.; Cemmi, A.; Mazzoni, V.; Stringer, L.D.; Zeni, V.; Ioriatti, C.; Anfora, G. The Competitive Mating of Irradiated Brown Marmorated Stink Bugs, Halyomorpha halys, for the Sterile Insect Technique. Insects 2019, 10, 411. [Google Scholar] [CrossRef] [Green Version]
  23. Horrocks, K.J.; Welsh, T.; Carpenter, J.E.; Suckling, D.M. Egg Sterilisation of Irradiated Nezara viridula (Hemiptera: Pentatomidae). Insects 2020, 11, 564. [Google Scholar] [CrossRef]
  24. de Beer, C.J.; Moyaba, P.; Boikanyo, S.N.B.; Majatladi, D.; Venter, G.J.; Vreysen, M.J.B. Gamma Irradiation and Male Glossina austeni Mating Performance. Insects 2020, 11, 522. [Google Scholar] [CrossRef] [PubMed]
  25. Yan, Y.; Williamson, M.E.; Scott, M.J. Using Moderate Transgene Expression to Improve the Genetic Sexing System of the Australian Sheep Blow Fly Lucilia cuprina. Insects 2020, 11, 797. [Google Scholar] [CrossRef]
  26. Bouyer, J.; Yamada, H.; Pereira, R.; Bourtzis, K.; Vreysen, M.J.B. Phased conditional approach for mosquito management using sterile insect technique. Trends Parasitol. 2020, 36, 325–336. [Google Scholar] [CrossRef] [Green Version]
  27. Lees, R.S.; Carvalho, D.O.; Bouyer, J. Potential impact of integrating the sterile insect technique into the fight against disease-transmitting mosquitoes. In Sterile Insect Technique: Principles and Practice in Area-Wide Integrated Pest Management, 2nd ed.; Dyck, V.A., Hendrichs, J., Robinson, A.S., Eds.; CRC Press: Boca Raton, FL, USA, 2021; pp. 1081–1118. [Google Scholar]
  28. Oliva, C.F.; Benedict, M.Q.; Collins, C.M.; Baldet, T.; Bellini, R.; Bossin, H.; Bouyer, J.; Corbel, V.; Facchinelli, L.; Fouque, F.; et al. Sterile Insect Technique (SIT) against Aedes Species Mosquitoes: A Roadmap and Good Practice Framework for Designing, Implementing and Evaluating Pilot Field Trials. Insects 2021, 12, 191. [Google Scholar] [CrossRef] [PubMed]
  29. Gouagna, L.C.; Damiens, D.; Oliva, C.F.; Boyer, S.; Le Goff, G.; Brengues, C.; Dehecq, J.-S.; Raude, J.; Simard, F.; Fontenille, D. Strategic Approach, Advances, and Challenges in the Development and Application of the SIT for Area-Wide Control of Aedes albopictus Mosquitoes in Reunion Island. Insects 2020, 11, 770. [Google Scholar] [CrossRef]
  30. Stefopoulou, A.; LaDeau, S.L.; Syrigou, N.; Balatsos, G.; Karras, V.; Lytra, I.; Boukouvala, E.; Papachristos, D.P.; Milonas, P.G.; Kapranas, A.; et al. Knowledge, Attitude, and Practices Survey in Greece before the Implementation of Sterile Insect Technique against Aedes albopictus. Insects 2021, 12, 212. [Google Scholar] [CrossRef]
  31. Marina, C.F.; Bond, J.G.; Hernández-Arriaga, K.; Valle, J.; Ulloa, A.; Fernández-Salas, I.; Carvalho, D.O.; Bourtzis, K.; Dor, A.; Williams, T.; et al. Population Dynamics of Aedes aegypti and Aedes albopictus in Two Rural Villages in Southern Mexico: Baseline Data for an Evaluation of the Sterile Insect Technique. Insects 2021, 12, 58. [Google Scholar] [CrossRef] [PubMed]
  32. Bond, J.G.; Aguirre-Ibáñez, S.; Osorio, A.R.; Marina, C.F.; Gómez-Simuta, Y.; Tamayo-Escobar, R.; Dor, A.; Liedo, P.; Carvalho, D.O.; Williams, T. Sexual Competitiveness and Induced Egg Sterility by Aedes aegypti and Aedes albopictus Gamma-Irradiated Males: A Laboratory and Field Study in Mexico. Insects 2021, 12, 145. [Google Scholar] [CrossRef]
  33. Tur, C.; Almenar, D.; Benlloch-Navarro, S.; Argilés-Herrero, R.; Zacarés, M.; Dalmau, V.; Pla, I. Sterile Insect Technique in an Integrated Vector Management Program against Tiger Mosquito Aedes albopictus in the Valencia Region (Spain): Operating Procedures and Quality Control Parameters. Insects 2021, 12, 272. [Google Scholar] [CrossRef] [PubMed]
  34. Gato, R.; Menéndez, Z.; Prieto, E.; Argilés, R.; Rodríguez, M.; Baldoquín, W.; Hernández, Y.; Pérez, D.; Anaya, J.; Fuentes, I.; et al. Sterile Insect Technique: Successful Suppression of an Aedes aegypti Field Population in Cuba. Insects 2021, 12, 469. [Google Scholar] [CrossRef]
  35. Vreysen, M.J.B.; Abd-Alla, A.M.M.; Bourtzis, K.; Bouyer, J.; Caceres, C.; de Beer, C.; Oliveira Carvalho, D.; Maiga, H.; Mamai, W.; Nikolouli, K.; et al. The Insect Pest Control Laboratory of the Joint FAO/IAEA Programme: Ten Years (2010–2020) of Research and Development, Achievements and Challenges in Support of the Sterile Insect Technique. Insects 2021, 12, 346. [Google Scholar] [CrossRef]
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MDPI and ACS Style

Bourtzis, K.; Vreysen, M.J.B. Sterile Insect Technique (SIT) and Its Applications. Insects 2021, 12, 638. https://doi.org/10.3390/insects12070638

AMA Style

Bourtzis K, Vreysen MJB. Sterile Insect Technique (SIT) and Its Applications. Insects. 2021; 12(7):638. https://doi.org/10.3390/insects12070638

Chicago/Turabian Style

Bourtzis, Kostas, and Marc J. B. Vreysen. 2021. "Sterile Insect Technique (SIT) and Its Applications" Insects 12, no. 7: 638. https://doi.org/10.3390/insects12070638

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