Saturday, January 18, 2020

Addressing Gender Inequality in Developing Countries Through Crop Improvement

A lot of production related benefits of biotechnology have been discussed in the literature, for instance decreased greenhouse gas emissions (Brookes and Barfoot, 2017), reduction in exposure to toxic chemicals (Kouser & Qaim, 2011), and food safety(Munkvold et. al, 1999). However additional research indicates that there may also be social benefits related to gender equality as discussed in
Social and Economic Effects of Genetically Engineered Crops (National Academies of Science, 2016).

Below are some highlights from this research:


  • Women comprise a significant proportion of agricultural related labor in developing countries (~43%)
  • Women in developing countries face significant challenges related to access to education, information, credit, inputs, assets, extension services, and land 

The adoption of biotechnology in developing countries has had some mitigating effects:

  • In India biotechnology adoption (Bt cotton) resulted in increased work hours and income for women (Subramanian and Qaim, 2010)
  • Reduced exposure and freeing women from spraying toxic chemicals and related labor (Bennett et al., 2003; Zambrano et al., 2013; Zambrano et al., 2012; Smale et al., 2012)
  • Increased importance of women in decision making within households (Yorobe and Smale, 2012; Zambrano et al., 2013; Rickson et al., 2006


References:

National Academies of Sciences, Engineering, and Medicine; Division on Earth and Life Studies; Board on Agriculture and Natural Resources; Committee on Genetically Engineered Crops: Past Experience and Future Prospects. Genetically Engineered Crops: Experiences and Prospects. Washington (DC): National Academies Press (US); 2016 May 17. 6, Social and Economic Effects of Genetically Engineered Crops. Available from: https://www.ncbi.nlm.nih.gov/books/NBK424536/

Graham Brookes & Peter Barfoot (2017) Environmental impacts of genetically modified (GM) crop use 1996–2015: Impacts on pesticide use and carbon emissions, GM Crops & Food, 8:2, 117-147, DOI: 10.1080/21645698.2017.1309490

Bennett R, Buthelezi TJ, Ismael Y, Morse S. Bt cotton, pesticides, labour and health: A case study of smallholder farmers in the Makhathini Flats, Republic of South Africa. Outlook on Agriculture. 2003;32:123–128.

Kouser, S., Qaim, M., Impact of Bt cotton on pesticide poisoning in smallholder agriculture: A panel data analysis,Ecol. Econ. (2011), doi:10.1016/j.ecolecon.2011.06.008

Comparison of Fumonisin Concentrations in Kernels of Transgenic Bt Maize Hybrids and Nontransgenic Hybrids. Munkvold, G.P. et al . Plant Disease 83, 130-138 1999.

Rickson ST, Rickson RE, Burch D. Women and sustainable agriculture. In: Bock BB, Shortall S, editors. Rural Gender Relations: Issues and Case Studies. Wallingford, UK: CABI Publishing; 2006. pp. 119–135.

Smale M, Zambrano P, Paz-Ybarnegaray R, Fernández-Montaño W. A case of resistance: Herbicide-tolerant soybeans in Bolivia. AgBioForum. 2012;15:191–205.

Subramanian A, Qaim M. The impact of Bt cotton on poor households in rural India. Journal of Development Studies. 2010;46:295–311

Yorobe JM Jr, Smale M. Impacts of Bt maize on smallholder income in the Phillipines. AgBioForum. 2012;15:152–162

Zambrano P, Smale M, Maldonado JH, Mendoza SL. Unweaving the threads: The experiences of female farmers with biotech cotton in Colombia. AgBioForum. 2012;15:125–137.

Zambrano P, Lobnibe I, Cabanilla DB, Maldonado JH, Falck-Zepeda J. Hiding in the plain sight: Women and GM crop adoption. Paper presented at the 17th ICABR Conference: Innovation and Policy for the Bioeconomy, June 18–21. Ravello, Italy: 2013.





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