Impact of CGIAR maize germplasm in Sub-Saharan Africa
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B. Prasanna | M. Bänziger | V. Krishna | O. Erenstein | T. Abdoulaye | M. A. Lantican | K. Pixley | A. Menkir
[1] O. Erenstein,et al. Global maize production, consumption and trade: trends and R&D implications , 2022, Food Security.
[2] V. Krishna,et al. Sustainable intensification under resource constraints: Estimating the heterogeneous effects of hybrid maize adoption in Nepal , 2022, Journal of Crop Improvement.
[3] Y. Beyene,et al. Host plant resistance for fall armyworm management in maize: relevance, status and prospects in Africa and Asia , 2022, Theoretical and Applied Genetics.
[4] Y. Beyene,et al. Genomic Analysis of Resistance to Fall Armyworm (Spodoptera frugiperda) in CIMMYT Maize Lines , 2022, Genes.
[5] T. Tefera,et al. Socioeconomic and health impacts of fall armyworm in Ethiopia , 2021, PloS one.
[6] E. Gasura,et al. Breeding strategy for resistance to Striga asiatica (L.) Kuntze based on genetic diversity and population structure of tropical maize (Zea mays L.) lines , 2021, Genetic Resources and Crop Evolution.
[7] P. Pardey,et al. Payoffs to a half century of CGIAR research , 2021, American Journal of Agricultural Economics.
[8] Ehtisham Shakeel Khokhar,et al. Quality protein maize (QPM): Importance, genetics, timeline of different events, breeding strategies and varietal adoption , 2021, Plant Breeding.
[9] O. Reynolds,et al. Global crop impacts, yield losses and action thresholds for fall armyworm (Spodoptera frugiperda): A review , 2021, Crop Protection.
[10] C. Magorokosho,et al. Multinutrient Biofortification of Maize (Zea mays L.) in Africa: Current Status, Opportunities and Limitations , 2021, Nutrients.
[11] A. B. Issa,et al. Beat the stress: breeding for climate resilience in maize for the tropical rainfed environments , 2021, Theoretical and Applied Genetics.
[12] K. Pixley,et al. Conservation and Use of Latin American Maize Diversity: Pillar of Nutrition Security and Cultural Heritage of Humanity , 2021, Agronomy.
[13] V. Krishna,et al. Farmer adoption of sustainable intensification technologies in the maize systems of the Global South. A review , 2021 .
[14] C. Ringler,et al. Accelerating rural energy access for agricultural transformation: contribution of the CGIAR Research Program on Water, Land and Ecosystems to transforming food, land and water systems in a climate crisis , 2021 .
[15] S. Holden,et al. Productivity impact of drought tolerant maize varieties under rainfall stress in Malawi: A continuous treatment approach , 2021 .
[16] Kurt B. Waldman,et al. Hybrid-maize seed certification and smallholder adoption in Zambia , 2021 .
[17] J. Stevenson,et al. Shining a Brighter Light: Comprehensive Evidence on Adoption and Diffusion of CGIAR-related Innovations in Ethiopia , 2020 .
[18] N. Poole,et al. Agri-nutrition research: Revisiting the contribution of maize and wheat to human nutrition and health , 2020, Food Policy.
[19] C. Kubitza,et al. Instrumental variables and the claim of causality: Evidence from impact studies in maize systems , 2020 .
[20] Edward Martey,et al. Welfare impacts of climate-smart agriculture in Ghana: Does row planting and drought-tolerant maize varieties matter? , 2020, Land Use Policy.
[21] N. Beintema,et al. Evolution of CGIAR funding , 2020 .
[22] M. Olsen,et al. Molecular Breeding for Nutritionally Enriched Maize: Status and Prospects , 2020, Frontiers in Genetics.
[23] O. Erenstein,et al. Impacts of drought-tolerant maize varieties on productivity, risk, and resource use: Evidence from Uganda , 2019, Land use policy.
[24] Prasanna M. Boddupalli,et al. Doubled haploid technology for line development in maize: technical advances and prospects , 2019, Theoretical and Applied Genetics.
[25] O. Erenstein,et al. Productivity and production risk effects of adopting drought-tolerant maize varieties in Zambia , 2019, International journal of climate change strategies and management.
[26] C. Magorokosho,et al. Impact of adoption of drought-tolerant maize varieties on total maize production in south Eastern Zimbabwe , 2017, Climate and development.
[27] Jostein Jakobsen. The maize frontier in rural South India: Exploring the everyday dynamics of the contemporary food regime , 2019, Journal of Agrarian Change.
[28] B. Creamer,et al. Identifying crop research priorities based on potential economic and poverty reduction impacts: The case of cassava in Africa, Asia, and Latin America , 2018, PloS one.
[29] B. Prasanna,et al. Developing and deploying climate-resilient maize varieties in the developing world , 2018, Current opinion in plant biology.
[30] T. Abdoulaye,et al. Impacts of improved maize varieties in Nigeria: ex-post assessment of productivity and welfare outcomes , 2018, Food Security.
[31] M. Zaman-Allah,et al. Gains in Maize Genetic Improvement in Eastern and Southern Africa: I. CIMMYT Hybrid Breeding Pipeline , 2017 .
[32] K. Tesfaye,et al. Climate change impacts and potential benefits of heat-tolerant maize in South Asia , 2017, Theoretical and Applied Climatology.
[33] Andrew J. Challinor,et al. Current warming will reduce yields unless maize breeding and seed systems adapt immediately , 2016 .
[34] R. Singh,et al. Impacts of international wheat improvement research, 1994-2014 , 2016 .
[35] Barry Smit,et al. Climate change, food security, and livelihoods in sub-Saharan Africa , 2016, Regional Environmental Change.
[36] T. Walker,et al. Crop Improvement, Adoption and Impact of Improved Varieties in Food Crops in Sub-Saharan Africa , 2015 .
[37] Awotide Diran Olawale,et al. Small-Scale Maize Seed Production in West and Central Africa: Profitability, Constraints and Options , 2015 .
[38] S. Tanumihardjo,et al. Biofortified orange maize is as efficacious as a vitamin A supplement in Zambian children even in the presence of high liver reserves of vitamin A: a community-based, randomized placebo-controlled trial , 2014, The American journal of clinical nutrition.
[39] Stephen Polasky,et al. Global agriculture and carbon trade-offs , 2014, Proceedings of the National Academy of Sciences.
[40] D. Zilberman,et al. Transgenic Crops, Production Risk, and Agrobiodiversity , 2014 .
[41] R. L. Rovere,et al. Potential impacts of increasing average yields and reducing maize yield variability in africa , 2013 .
[42] J. de Haan,et al. Conditional Election and Partisan Cycles in Government Support to the Agricultural Sector: An Empirical Analysis , 2013 .
[43] Paul W. Heisey,et al. ASTI Global assessment of agricultural R&D spending: developing countries accelerate investment , 2012 .
[44] S. Mohanty,et al. Support for international agricultural research: current status and future challenges. , 2010, New biotechnology.
[45] Derek Byerlee,et al. The impacts of CGIAR research: A review of recent evidence , 2010 .
[46] H. Groote,et al. A meta-analysis of community-based studies on quality protein maize , 2010 .
[47] A. Alene,et al. The economic and poverty impacts of maize research in West and Central Africa. , 2009 .
[48] David A. Raitzer,et al. Benefit-cost meta-analysis of investment in the International Agricultural Research Centers of the CGIAR , 2008 .
[49] V. Krishna,et al. Potential impacts of Bt eggplant on economic surplus and farmers' health in India , 2008 .
[50] J. Araus,et al. Recent Advances in Breeding Maize for Drought and Salinity Stress Tolerance , 2007 .
[51] Robert E. Evenson,et al. Crop Variety Improvement and its Effect on Productivity: The Impact of International Agricultural Research , 2003 .
[52] R. Evenson,et al. Impact of IITA germplasm improvement on maize production in West and Central Africa. , 2003 .
[53] Robert E. Evenson,et al. Impacts of CIMMYT maize breeding research. , 2003 .
[54] James F. Oehmke,et al. Science under scarcity: Principles and practice for agricultural research evaluation and priority setting , 1996 .
[55] R. Blundell,et al. Initial Conditions and Moment Restrictions in Dynamic Panel Data Models , 1998 .
[56] M. Arellano,et al. Another look at the instrumental variable estimation of error-components models , 1995 .
[57] M. L. Morris,et al. Impacts of international maize breeding research in the developing world, 1966-1990 , 1994 .
[58] P. Moya,et al. Impacts of international wheat breeding research in the developing world , 1993 .
[59] M. Arellano,et al. Some Tests of Specification for Panel Data: Monte Carlo Evidence and an Application to Employment Equations , 1991 .