Abstract
Since the 1990s, agri-biotech multinationals have introduced a radical innovation in the form of seeds derived from genetically modified plant varieties or GMVs. However, on the basis of the ‘precautionary principle’ that advocates ensuring a higher environmental protection through preventative decision-taking, many countries have banned the cultivation of GMVs within their territories. Thus, the objective of the present paper is to attempt to explore the rationale for application of the precautionary principle. This is done through development of an evolutionary model of farmers’ technology choice incorporating intrinsic features of agriculture such as the technological obsolescence of seed varieties, impact of environmental degradation engendered by new seed technology adoption and farmers’ compliance choice vis-à-vis sustainability guidelines. Further, instead of a unique representative farmer, two types of farmers are considered. The first type is driven by short term profit maximization, while the second type aims to be sustainable, by maximizing profit over the life time of the technology. Integrating the above elements and considering two possible rules for application of the precautionary principle, the paper explores the conditions under which the precautionary principle can be implemented. It demonstrates that, even under complete and perfect information the need to exercise such caution depends principally on four factors: the economic gains from GMVs, the possibilities for sustaining the production of the conventional variety in the post-GMV period via compliance, the distribution of farmers over types and the compliance-contamination burden.
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Change history
08 September 2022
The book was inadvertently published with its Chapters 6, 7, 10, 11, 12, 14, 16 having an incorrect “Copyright Holder Name” and “Copyright Year” information. The reprinting information in the footnotes of these Spin-Off chapters were also missed to be included to these 7 chapters.
Notes
- 1.
The Green Revolution was a technology package involving improved quality seeds, controlled irrigation and measured doses of fertilizers. Created by the agricultural scientist Norman Borlaug, these modern variety seeds were a new dwarf variety of wheat, with “short legs” that could support a greater amount of wheat grains on any stalk. The hybrid dwarf variety clearly yielded more than the conventional varieties of wheat of that time. While the Green Revolution heralded a veritable increase in yields with respect to cereals, and saved developing countries, especially India, from famine, it led to very intensified use of water and application of agro-chemicals causing soil degradation and groundwater depletion.
- 2.
Interested readers can obtain examples of precise functional forms of the profit and payoff functions that satisfy these properties from the authors.
- 3.
Following the World Bank Country Classification by Income https://datahelpdesk.worldbank.org/knowledgebase/articles/906519-world-bank-country-and-lending-groups
References
Adenle AA, Morris EJ, Murphy DJ, Phillips PW, Trigo E, Kearns P et al (2018) Rationalizing governance of genetically modified products in developing countries. Nat Biotechnol 36(2):137
Anderson JR, Feder G (2004) Agricultural extension: good intentions and hard realities. World Bank Res Obs 19(1):41–60
Anderson JA, Ellsworth PC, Faria JC, Head GP, Owen MD, Pilcher CD et al (2019) Genetically engineered crops: importance of diversified integrated pest management for agricultural sustainability. Frontiers in Bioengineering and Biotechnology 7:24
Areal F, Riesgo L, Rodriguez-Cerezo E (2013) Economic and agronomic impact of commercialized GM crops: a meta-analysis. J Agric Sci 151(1):7–33
Arrow KJ, Fisher AC (1974) Environmental preservation, uncertainty, and irreversibility. Q J Econ 88:187–191
Aslam U, Termansen M, Fleskens L (2017) Investigating farmers’ preferences for alternative PES schemes for carbon sequestration in UK agroecosystems. Ecosystem Services 27:103–112
Beharry-Borg N, Smart JC, Termansen M, Hubacek K (2013) Evaluating farmers’ likely participation in a payment programme for water quality protection in the UK uplands. Reg Environ Chang 13(3):633–647
Belcher K, Nolan J, Phillips PW (2005) Genetically modified crops and agricultural landscapes: spatial patterns of contamination. Ecol Econ 53(3):387–401
Bogner A, Torgersen H (2018) Precaution, responsible innovation and beyond—in search of a sustainable agricultural biotechnology policy. Frontiers in Plant Science 9:1884
Cai Y, Kim E (2019) Sustainable development in world trade law: application of the precautionary principle in Korea-radionuclides. Sustainability 11(7):1942
Caplan AL, Parent B, Shen M, Plunkett C (2015) No time to waste—the ethical challenges created by CRISPR. EMBO Rep 16(11):1421–1426
Carpenter JE (2010) Peer-reviewed surveys indicate positive impact of commercialized GM crops. Nat Biotechnol 28(4):319
Castro D, McLaughlin M (2019) Ten ways the precautionary principle undermines progress in artificial intelligence. Retrieved from https://itif.org/publications/2019/02/04/ten-ways-precautionary-principle-undermines-progress-artificial-intelligence
Catarino R, Ceddia G, Areal FJ, Park J (2015) The impact of secondary pests on Bacillus thuringiensis (Bt) crops. Plant Biotechnol J 13(5):601–612
Ceddia MG, Bartlett M, Perrings C (2007) Landscape gene flow, coexistence and threshold effect: the case of genetically modified herbicide tolerant oilseed rape (Brassica napus). Ecol Model 205(1–2):169–180
Ceddia MG, Bartlett M, Perrings C (2009) Quantifying the effect of buffer zones, crop areas and spatial aggregation on the externalities of genetically modified crops at landscape level. Agric Ecosyst Environ 129(1–3):65–72
Christensen T, Pedersen AB, Nielsen HO, Mørkbak MR, Hasler B, Denver S (2011) Determinants of farmers’ willingness to participate in subsidy schemes for pesticide-free buffer zones—a choice experiment study. Ecol Econ 70(8):1558–1564
Christiansen A (2019) Rationality, expected utility theory and the precautionary principle. Ethics Policy Environ 1–18
David PA (1975) Technical choice innovation and economic growth: essays on American and British experience in the nineteenth century. Cambridge University Press, New York
Feder G, Umali DL (1993) The adoption of agricultural innovations: a review. Technol Forecast Soc Chang 43(3–4):215–239
Feder G, Just RE, Zilberman D (1985) Adoption of agricultural innovations in developing countries: a survey. Econ Dev Cult Chang 33(2):255–298
Friesen LF, Nelson AG, Van Acker RC (2003) Evidence of contamination of pedigreed canola (Brassica napus) seedlots in western Canada with genetically engineered herbicide resistance traits. Agron J 95(5):1342–1347
Giampietro M (2002) The precautionary principle and ecological hazards of genetically modified organisms. Ambio 31(6):466–470
Gilbert N (2013) A hard look at GM crops. Nature. 497:24–26
Gliessman SR (1990) Agroecology: researching the ecological basis for sustainable agriculture. Springer, New York
Gollier C, Jullien B, Treich N (2000) Scientific progress and irreversibility: an economic interpretation of the ‘precautionary principle’. J Public Econ 75(2):229–253
Gorlin JB (2019) Iron replacement: precautionary principle versus risk-based decision making. Transfusion 59(5):1613–1615
Griliches Z (1957) Hybrid corn: an exploration in the economics of technological change. Econometrica 25:501–522
Hayami Y, Ruttan VW (1971) Agricultural development: an international perspective. The Johns Hopkins Press, Baltimore
Henry C (1974) Investment decisions under uncertainty: the “irreversibility effect”. Am Econ Rev 64(6):1006–1012
Huang F, Andow DA, Buschman LL (2011) Success of the high-dose/refuge resistance management strategy after 15 years of Bt crop use in North America. Entomol Exp Appl 140(1):1–16
Immordino G (2003) Looking for a guide to protect the environment: the development of the precautionary principle. J Econ Surv 17(5):629–644
ISAAA (2018) Global status of commercialized biotech/GM crops: 2018. ISAAA Brief No. 54. ISAAA. Ithaca, NY
Ishii T (2018) Crop gene-editing: should we bypass or apply existing GMO policy? Trends Plant Sci 23(11):947–950
Jin L, Zhang H, Lu Y, Yang Y, Wu K, Tabashnik BE et al (2015) Large-scale test of the natural refuge strategy for delaying insect resistance to transgenic Bt crops. Nat Biotechnol 33(2):169
Klerkx L, Van Mierlo B, Leeuwis C (2012) Evolution of systems approaches to agricultural innovation: concepts, analysis and interventions. Springer, Dordrecht
Levidow L (2001) Precautionary uncertainty: regulating GM crops in Europe. Soc Stud Sci 31(6):842–874
Lu Y, Wu K, Jiang Y, Xia B, Li P, Feng H et al (2010) Mirid bug outbreaks in multiple crops correlated with wide-scale adoption of Bt cotton in China. Science 328(5982):1151–1154
Miller HE, Engemann KJ (2019) The precautionary principle and unintended consequences. Kybernetes 48(2):265–286
Murgai R, Ali M, Byerlee D (2001) Productivity growth and sustainability in post-green revolution agriculture: the case for the Indian and Pakistan Punjabs. World Bank Res Obs 16:199–218
Noailly J (2008) Coevolution of economic and ecological systems. J Evol Econ 18(1):1–29
Orset C (2014) Innovation and the precautionary principle. Econ Innov New Technol 23(8):780–801
Ortega DL, Waldman KB, Richardson RB, Clay DC, Snapp S (2016) Sustainable intensification and farmer preferences for crop system attributes: evidence from Malawi’s central and southern regions. World Dev 87:139–151
Pant LP (2019) Responsible innovation through conscious contestation at the interface of agricultural science, policy, and civil society. Agric Hum Values 1–15
Peng S, Cassman KG, Virmani S, Sheehy J, Khush GS (1999) Yield potential trends of tropical rice since the release of IR8 and the challenge of increasing rice yield potential. Crop Sci 39:1552–1559
Peng S, Huang J, Cassman KG, Laza RC, Visperas RM, Khush GS (2010) The importance of maintenance breeding: a case study of the first miracle rice variety-IR8. Field Crop Res 119(2):342–347
Prakash A, Kollman KL (2003) Biopolitics in the EU and the US: a race to the bottom or convergence to the top? Int Stud Q 47(4):617–641
Ramani SV, Richard A (1993) Decision, irreversibility and flexibility: the irreversibility effect re-examined. Theor Decis 35(3):259–276
Ramani SV, Thutupalli A (2015) Emergence of controversy in technology transitions: green revolution and Bt cotton in India. Technol Forecast Soc Chang 100:198–212
Reisig DD, Kurtz R (2018) Bt resistance implications for Helicoverpa zea (Lepidoptera: Noctuidae) insecticide resistance management in the United States. Environ Entomol 47(6):1357–1364
Ruto E, Garrod G (2009) Investigating farmers’ preferences for the design of agri-environment schemes: a choice experiment approach. J Environ Plan Manag 52(5):631–647
Sandin P (1999) Dimensions of the precautionary principle. Hum Ecol Risk Assess 5(5):889–907
Shiva V (1989) The violence of the green revolution—ecological degradation and political conflict in Punjab. Natraj Publisher, Dehra Dun
Singla R, Johnson P, Misra S (2013) Examination of regional-level efficient refuge requirements for Bt cotton in India. AgBioForum. 15(3):303–314
Sunding D, Zilberman D (2001) The agricultural innovation process: research and technology adoption in a changing agricultural sector. Handb Agric Econ 1:207–261
Swanson TM (2002) Biotechnology, agriculture and the developing world: the distributional implications of technological change. Edward Elgar Publishing Ltd., Northampton
Szirmai A (2005) The dynamics of socio-economic development: an introduction. Cambridge University Press, Cambridge
Tabashnik BE, Carrière Y (2017) Surge in insect resistance to transgenic crops and prospects for sustainability. Nat Biotechnol 35(10):926
Tabashnik BE, Gassmann AJ, Crowder DW, Carrière Y (2008) Insect resistance to Bt crops: evidence versus theory. Nat Biotechnol 26(2):199
Tisdell C (2010) The precautionary principle revisited: its interpretations and their conservation consequences. Singap Econ Rev 55(02):335–352
Van der Werf HM, Petit J (2002) Evaluation of the environmental impact of agriculture at the farm level: a comparison and analysis of 12 indicator-based methods. Agric Ecosyst Environ 93(1–3):131–145
Voytas DF, Gao C (2014) Precision genome engineering and agriculture: opportunities and regulatory challenges. PLoS Biol 12(6):e1001877
Weaver SA, Morris MC (2005) Risks associated with genetic modification:–an annotated bibliography of peer reviewed natural science publications. J Agric Environ Ethics 18(2):157–189
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Ramani, S.V., El-Aroui, MA. (2020). On application of the precautionary principle to ban GMVs: an evolutionary model of new seed technology integration. In: Pyka, A., Lee, K. (eds) Innovation, Catch-up and Sustainable Development. Economic Complexity and Evolution. Springer, Cham. https://doi.org/10.1007/978-3-030-84931-3_16
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