Data has become a key driver of growth and change in today’s world.
There is growing recognition that data is indispensable for effective planning and decision-making in every sector. But the state of digital data in developing countries is far from satisfactory. In Asia, monitoring the Sustainable Development Goals (SDGs) remains a challenge due to a lack of accurate data.
Pawan Kumar Singh, head, wheat pathology, International Maize and Wheat Improvement Center (CIMMYT) says that the fast-acting and devastating fungal disease known as wheat blast was first spotted in Africa in the Zambian rainfed wheat production system in the 2017-2018 crop cycle.
Agriculture contributes significantly to greenhouse gases (GHGs), so can farmers be incentivized to cultivate in a less earth-warming manner, with tradable carbon credits giving them an additional source of income?
Andrea Gardeazábal has many titles — Monitor, Evaluation and Learning Manager, ICT for Agriculture — but the core of what she does is knowledge management. She merges monitoring, evaluation, accountability and learning (MEAL) with information communication technologies (ICT) to transform data into something meaningful.
A political scientist by training, Gardeazábal knows the power of data and statistics. As she began working on ICT-for-development projects in the field, she observed a lack of understanding of ICT and how the development sector could take advantage of these tools.
“I knew this was progressing very fast; that this was the future. Everyone was talking about ICT and the future with the internet of things, and social media was just getting started,” she said. So she asked herself, how could the development sector take advantage of these new technologies?
Gardeazábal was working on projects bringing computers to rural areas in Colombia, which did not have internet connection or electricity. The problem could not be solved simply with a machine. She wanted to understand how to use ICT for development in a meaningful way. This triggered an interest in MEAL, to understand how ICT benefits the development sector, or does not, and to reintegrate that information into project design and impact.
After working in ICT for civil participation, education and microfinance, she joined CIMMYT with the mission to understand ICT for agriculture. Now she merges ICT tools with MEAL, leading the design, development and operation of systems for data collection, data cleaning, data analysis and data visualization with the Integrated Development program’s projects in Colombia, Guatemala and Mexico.
Ensuring intended results
Monitoring, learning, accountability and evaluation is crucial to ensure CIMMYT delivers on its objectives. Monitoring means ensuring that operations in the field are happening as planned. Rather than waiting until the end of the project when the donor asks for a report, Gardeazábal’s team monitors operations in the field on a quarterly or yearly basis. The team, both in the field and at headquarters, uses this data to check that the project is achieving what was intended and make interventions or adjustments if necessary.
Evaluation looks at project results and evidence. The team collects evidence for every single data point that they have, and then evaluates that evidence for impact and results in the field. This data is not only related to yield increase, but includes sustainable production, capacity development, and adequate technology adaptation and adoption processes.
Accountability is transparency with funders, so that everyone involved in a project is accountable for the processes, decisions and impact. CIMMYT is able to show progress through a transparent relationship with funders.
Learning happens after the team collects information, produces results evaluations, and understands what was done well and where the process had to be redirected. This information can then inform design of new projects or project phases. “We use the data and analysis of each project to redesign or modify our plans for the next project or even what kinds of projects we want to conduct,” Gardeazábal said.
Andrea Gardeazábal merges ICT tools with monitoring, evaluation, accountability and learning to improve project design. (Photo: Francisco Alarcón/CIMMYT)
What ICT can offer
In the past, a MEAL team would collect data from a representative sample at the start of the project, then go back to the office and analyze that data. At the end of the project, the team would complete the same exercise, to see the difference from what they gathered at the beginning.
With ICT tools, researchers are able to gather and analyze robust data more quickly and can communicate efficiently with the beneficiaries of a project throughout its course. Artificial intelligence and machine learning algorithms can help in understanding large sets of data so that this information can strengthen and streamline the MEAL process and project impact.
“We don’t need to wait until the end of the project for the results in the field or to have a sense of what the farmers are saying and achieving. We have a lot of tools, from the ICT side, that help make monitoring and evaluation more efficient,” Gardeazábal explained.
An international award recognized some of these ICT tools earlier this year. Gardeazábal formed part of the winning team with members from the Alliance of Bioversity International and CIAT and the International Institute for Applied Systems Analysis (IIASA) working on groundbreaking data systems and tools that help over 150,000 farmers in Mexico.
The team tracked over 500 variables over different farming plots and analyzed them with geographic, weather and market data to help identify the best management practices for each plot. This information — including historic yield potential, local benchmarks, windows of opportunity, recommended agricultural practices and commodity price forecasting — is available to farmers through an app called AgroTutor (Android, iOS).
The importance of an enabling environment
However, Gardeazábal cautions against the idea that technology on its own is going to end poverty or increase food security.
“ICT is a vehicle for innovation in agriculture. Just having an app in the field is not enough to generate the change that we are actually looking for. You need an enabling environment, a network, engagement of the farmers and the buy-in of scientists to take advantage of ICT tools.”
From drones and satellite imagery to artificial intelligence, ICT tools can help CIMMYT carry out its mission by streamlining the data gathering and analytics processes.
However, this work is not done in isolation from the environment surrounding it. CIMMYT does not only work on increasing yields, but also manages resources and local networks in efficient ways. Teams must monitor data on air quality, water use and efficient information flows, analyze this data, and then return to the field with recommendations for the most sustainable production within integrated agri-food systems.
Maize and wheat fields at CIMMYT’s El Batán experimental station. (Photo: Alfonso Cortés/CIMMYT)
The International Maize and Wheat Improvement Center (CIMMYT) is pleased to announce the release of a new category of maize inbred lines called CIMMYT Maize Genetic Resource Lines (CMGRL). The CMGRLs are derived from crosses between elite CIMMYT lines and landrace accessions, populations or synthetics from the CIMMYT Germplasm Bank.
Although high standards of yield and agronomic performance are applied in their selection, CMGRLs are not intended to be used directly in commercial hybrids but rather by breeders as sources of novel alleles for traits of economic importance. These lines should also be of interest to maize researchers who are not breeders but are studying the underlying genetic mechanisms of abiotic and biotic traits.
A tar spot disease resistant line next to a non-resistant line. (Photo: Terry Molnar/CIMMYT)
Currently the maize genetic resources breeding team has projects in drought tolerance, heat tolerance, tar spot complex (TSC) disease resistance and in the development of lines and hybrids with blue kernel color. For all of these projects, the best lines identified for a given trait objective will be recombined to produce open-pollinated varieties that will be made available to the public.
The inaugural class of CMGRLs includes five subtropical adapted lines for tolerance to drought during flowering and grain-fill and four tropical adapted lines for TSC resistance. Both phenotypic and genotypic data will be published online for all CMGRL releases. CIMMYT will periodically release CMGRLs as superior lines are identified for economically important abiotic and biotic stresses as well as end-use traits.
Release Summary:
CMGRL Name
Trait Target
Type
Level
Landrace Donor Parent
Landrace Country of Origin
Recurrent Parent
Heterotic Group
Adaptation
CMGRLB001
TSC resistance
BC1
S5
OAXA280
Mexico
CML576
B
Tropical
CMGRLB002
TSC resistance
BC1
S5
OAXA280
Mexico
CML576
B
Tropical
CMGRLB003
TSC resistance
BC1
S5
GUAT153
Guatemala
CML576
B
Tropical
CMGRLB004
TSC resistance
BC1
S5
GUAT153
Guatemala
CML576
B
Tropical
CMGRLB005
Drought tolerance
BC1
S5
ARZM12193
Argentina
CML376
B
Subtropical
CMGRLB006
Drought tolerance
BC1
S5
ARZM12237
Argentina
CML376
B
Subtropical
CMGRLB007
Drought tolerance
BC1
S5
SNLP169
Mexico
CML376
B
Subtropical
CMGRLB008
Drought tolerance
BC1
S5
SNLP17
Mexico
CML376
B
Subtropical
CMGRLB009
Drought tolerance
BC1
S5
SNLP17
Mexico
CML376
B
Subtropical
Full details including phenotypic and genotypic data on the nine lines are available here. To order a 50-kernel seed sample of the CMGRLs, please contact Terry Molnar.
“We are unlikely to see big peaks in stubble burning unlike the previous years. The burning of paddy residue is likely to be more evenly distributed across a longer period,” said M.L. Jat, principal scientist at the International Maize and Wheat Improvement Center (CIMMYT).
Fall armyworm continues to cause havoc in Africa. Farmers in Somalia have not been spared since this unwelcome guest showed up in the country over three years ago. As part of the mitigation measures, the Somali Agriculture Technical Group (SATG) in partnership with the International Maize and Wheat Improvement Center (CIMMYT) and the International Committee of the Red Cross (ICRC) recently conducted online trainings on fall armyworm management for sustainable crop protection. The online trainings, targeting national agriculture stakeholders in the country, took place on August 25 and September 30, 2020, with nearly 250 participants attending both webinars.
“This is the first of our efforts to reach out to our partners in Somalia, especially the Somali Agriculture Technical Group and the national agricultural research system, to increase the awareness on the integrated pest management approaches that can help combat this highly destructive pest,” said B.M. Prasanna, Director of CIMMYT’s Global Maize Program and the CGIAR Research Program on Maize (MAIZE).
“This training was designed to help participants to gain a better understanding about fall armyworm, how to identify it, how to monitor and scout for it, how to effectively implement a management strategy that is environmentally and ecologically benign, in order to protect the food security and livelihoods of farmers and their families,” Prasanna said.
An integrated pest management strategy for sustainable control of fall armyworm should consider various interventions, including regular scouting and monitoring of the pest in the fields, host plant resistance, biological and biorational control, agroecological management, and use of environmentally safer pesticides and good agronomic practices tailored for the socio-cultural and economic contexts of the farmers. Ultimately, the purpose of a functional integrated pest management approach is to suppress pest population by applying techniques that minimize human and environmental harm, while protecting the crops from economic damage.
“I am happy to see the expertise from high levels of research at CIMMYT, icipe, IITA, universities, SATG and the humanitarian sector coming together to tackle and solve problems linked to food production and consumption. I believe that such important trainings have great value for Somalia, and should be further strengthened and encouraged,” said Abdalla Togola from the ICRC.
B.M. Prasanna, Director of CIMMYT Global Maize Program and the CGIAR Research Program MAIZE, presents at the online training on integrated pest management-based fall armyworm control. (Photo: Joshua Masinde/CIMMYT)
Hussein Haji, the Executive Director of Somali Agriculture Technical Group speaks at the fall armyworm online training on integrated pest management-based fall armyworm control. (Photo: Joshua Masinde/CIMMYT)
Professor Dan McGrath of Oregon State University, USA, delivering a training on integrated pest management-based fall armyworm control. (Photo: Joshua Masinde/CIMMYT)
John Karonga, an agronomist at the International Committee of the Red Cross (ICRC) speaks at the online training on integrated pest management-based fall armyworm control. (Photo: Joshua Masinde/CIMMYT)
Hussein Haji, the Executive Director of SATG was optimistic that the training would go a long way to empower farmers in Somalia, through their cooperatives, and could lead to better ways of tackling challenges such as fall armyworm, already made worse by other stresses like drought and desert locusts.
“Through our extension workers, we hope this information will trickle down to our cooperatives, who produce mainly maize and sorghum seed in Somalia,” he added.
This comes on the back of a partnership between the ICRC and SATG to implement activities intended to improve food production among rural communities in six regions of Somalia. The partnership would enhance quality seed production with a focus on maize and sorghum, the major staple crops in the country.
Besides Prasanna, the key resource persons included Dan McGrath (Professor Emeritus, Oregon State University, USA), Joseph Huesing (CIMMYT Consultant on integrated pest management) and Georg Goergen (Entomologist, International Institute of Tropical Agriculture), Frederic Baudron (CIMMYT Systems Agronomist), Anani Bruce (CIMMYT Entomologist), Yoseph Beyene (CIMMYT Regional Breeding Coordinator for Africa) and Saliou Niassy (Head of Agricultural Technology Transfer Unit, International Center of Insect Physiology and Ecology).
The fall armyworm, a voracious caterpillar officially reported for the first time in Africa in Nigeria in 2016, remains a serious pest with devastating consequences on millions of farmers’ food and livelihood security. The pest has spread quickly throughout sub-Saharan Africa, primarily attacking maize and sorghum, two main staple crops in the region. The Food and Agriculture Organization of the United Nations (FAO) estimates up to 18 million tons of maize are lost to the pest annually, at an estimated economic loss of $4.6 billion.
To reduce the losses, experts have been recommending a toolbox of integrated pest management (IPM) practices to minimize the damage on smallholder farmers’ fields. Scientists at CIMMYT are also working intensively to develop improved maize varieties with native genetic resistance to this devastating insect pest.
Cover photo: Kowthar Abdirahman Afyare studies agriculture at the Somali National University. (Photo: AMISOM Public Information)
For three years, Kellogg, in partnership with the International Center for the Improvement of Corn and Wheat (CIMMYT), has been working on a program which seeks to provide technical and scientific advice to increase the productivity of land and efficient use of available natural resources, so farmers obtain better crops and have more profitable economic activities that mitigate the effects of climate change.
With global agriculture in stasis and under threat from climate change, Latin America’s role to address these challenges through innovation and partnerships is crucial. This was the main takeaway from a 2020 World Food Prizeroundtable event, where representatives from four CGIAR centers discussed opportunities for increased investment in Latin America for developing innovations to improve global agriculture and agro-biodiversity.
The event was moderated by Natasha Santos, the Vice President of Global Stakeholders Strategy and Affairs for Bayer Crop Sciences. Speaking online from Brazil, Santos stressed the importance of private sector partnerships in Latin America for achieving sustainable growth and development.
Jesus Quintana, the Managing Director for the Americas, the Alliance of Bioversity International and CIAT opened the event with a short description of his organization’s work with development finance to promote sustainable development in the Amazon. “With USAID,” he said, “we are searching for business models that strengthen local innovations and social businesses to conserve biodiversity, including agri-food systems.”
Picking up on the idea of agri-food systems, Bram Govaerts, Interim Deputy Director General, Director of Integrated Development and Representative for the Americas, International Maize and Wheat Improvement Center (CIMMYT), noted that the World Food Programme will receive the Nobel Peace Prize 50 years after Norman Borlaug – whose work was the inspiration for the CGIAR – became the first recipient of the prestigious award from the fields of food and agriculture. The span between awards, Govaerts said, serves as notice that much important work still remains in the fight against hunger and nutrition insecurity worldwide.
In this vein, Govaerts described CIMMYT’s work with a program called AgroTutor, which delivers site-specific data and recommendations tailored to farmers’ needs that help improve yields and facilitate more profitable market interactions.
The continuing mission to eradicate global hunger and promote development in the face of climate change can be uniquely addressed in the Andes, said Ginya Truitt Nakata, Regional Director for Latin America and the Caribbean, International Potato Center (CIP). Home to 85 of the world’s 110 biological life zones, Truitt Nakata said CIP’s Andean Initiative would use the mountains as a living laboratory for co-investigation of agricultural challenges with networks of smallholder farmers.
“The data and lessons we draw from these spaces will have application for farmers around the world,” she said.
As the event centered around recent CGIAR innovations in Latin American, Ruben G. Echeverría, Senior Research Fellow, International Food Policy Research Institute (IFPRI), said the greatest need, system-wide, is the bottleneck of ideas and innovations prior to implementation. For this reason, IFPRI is developing project incubation facilities to scale up innovations for stronger, further-reaching impact with farmers. “This work requires partnerships with public and private finance to help transform our knowledge into impact for food systems,” he said.
Following the short presentations, the roundtable opened a conversation that focused on the need for inclusiveness in research, private sector partnerships, and data collection supported by monitoring and learning.
“As the CG system, we are talking about participatory development with farmers – women, men and youth. It takes a little longer but the adoption rates [of innovation] are much higher,” Truitt Nakata said.
Agriculture in Latin America, like other regions of the world, also struggles with “brain drain,” losing talented young people to other sectors of the employment market. “So, when we talk about youth,” Echeverría responded, “We need more than participation. It’s about attracting young people to agricultural opportunities through IT and finance.”
Focusing on the technical side of innovation, Govaerts and Quintana cited the need for improved use of data.
“We need to multi-purpose data and use monitoring in real time to ensure better return on investment,” said Govaerts, “We need to know where we made progress and where we made mistakes.” Quintana endorsed that sentiment, “Careful monitoring of projects should be the heart of collaborative work, to generate baselines so we can accurately measure our impact and make more responsible use of resources.”
Given the wealth of ideas exchanged in the hour-long event, Marco Ferroni, the Chair of the CGIAR System Management Board, said the presentations showed the indispensable value of the region’s to food system and agrobiodiversity research.
“Latin America is the world’s largest food exporting region and important producer of ecosystem services that shape global weather patterns and climate… Motivated by the need to increase the scope of our impact, partnerships help us achieve critical mass in terms of data, analysis and delivery to stakeholders. For all these reasons, and others, Latin American food systems need and deserve policy attention and investment,” Ferroni said.
By 2050, the world’s population could grow to 9.7 billion, food demand is expected to increase by 50% and global demand for grains such as maize, rice and wheat could increase by 70%. How can we meet the food and nutrition demands of a rising population, without negative environmental and social consequences?
Sustainable intensification is an approach using innovations to increase productivity on existing agricultural land with positive environmental and social impacts. Both words, “sustainable” and “intensification,” carry equal weight.
CIMMYT conducts research on sustainable intensification to identify ways farmers can increase production of crops per unit of land, conserve or enhance important ecosystem services and improve resilience to shocks and stresses, especially those due to climate change and climate variability.
For example, CIMMYT’s research on sustainable intensification in India has helped shape policies that increase farmer income while reducing pollution and land degradation.
What is the scope of sustainable intensification?
Sustainable intensification takes into consideration impact on overall farm productivity, profitability, stability, production and market risks, resilience, as well as the interests and capacity of individual farmers to adopt innovations. It is not limited to environmental concerns, but also includes social and economic criteria such as improving livelihoods, equity and social capital.
Certain methods and principles are needed to achieve the goals of sustainable intensification. In collaboration with farmers and other change actors, CIMMYT carries out research-for-development projects to test and scale a range of technologies and approaches that contribute to these results. The research focuses on combined resource use efficiencies of crop production inputs: land, plant nutrients, labor and water.
One example is conservation agriculture, the combination of crop diversification, minimal soil movement and permanent soil cover. International scientific analysis has found that conservation agriculture can, in many places with different characteristics, play a crucial role towards achieving the United Nations Sustainable Development Goals.
Crop and system modeling, geographic information systems, remote sensing, scale-appropriate mechanization and socioeconomic modeling are some of the approaches that contribute to the design and evaluation of sustainable intensification alternatives in current farming systems.
Figure: Multi-criteria sustainability assessment of alternative (sustainable intensification) and reference systems in the Western Highlands of Guatemala.
What are some more examples?
Several interventions by CIMMYT aim at safeguarding biodiversity and protecting — in some cases increasing — ecosystem services crucial for small-scale farmers’ livelihoods and the health of all. Others have studied the impact of landscapes on dietary diversity and nutrition. Yet others have developed appropriate small-scale machines, allowing farmers to save time, costs and labor associated with agriculture to increase yields, halt the expansion of the agricultural frontier and invest in new opportunities.
How is sustainable intensification different from ecological intensification, agroecological intensification or climate-smart agriculture?
Sustainable intensification, ecological intensification and agroecological intensification strive for the same general goal to feed an increasing population without negative environmental and social consequences, but they place emphasis on different aspects.
Ecological intensification focuses on ecological processes in the agroecosystem. Agroecological intensification emphasizes a systems approach and strongly considers social and cultural perspectives.
Climate-smart agriculture and sustainable intensification are complementary, but climate-smart agriculture focuses on climate stress, adaptation and mitigation.
Sustainable intensification can be achieved with a range of methods, including these concepts. It is one strategy among many for global food system transformation.
What is the history of CIMMYT’s research on sustainable intensification?
In the 1960s, the Green Revolution brought high-yielding crops to some regions of Latin America and South Asia, allegedly saving millions from starvation. Yet the Green Revolution had unintended environmental and social consequences. Critics of the Green Revolution argued these cropping techniques were highly dependent on external inputs, fossil fuels and agrochemicals, causing environmental damage through overuse of fertilizers and water, and contributing to soil degradation.
In the 1980s, CIMMYT scientists began placing stronger emphasis on environmental and social aspects — such as conserving soil and water, and ensuring social inclusion of marginalized groups — recognizing their importance to sustain the intensification of crops in South Asia. It was understood that sustainability includes improving the livelihoods of rural people who depend on these natural resources, in addition to better resource management. CIMMYT began to take these considerations to the core of its work.
Farmers Maliamu Joni and Ruth Andrea harvest cobs of drought-tolerant maize in Mbeya, Tanzania. (Photo: Peter Lowe/CIMMYT)
Are these practices successful?
Sustainable intensification can boost yields, increase farmers’ profits and reduce greenhouse gas emissions. The reduction of greenhouse gas emissions can be achieved by increasing nitrogen use efficiency, which also reduces groundwater pollution.
Research from CIMMYT’s SIMLESA project has shown that conservation agriculture-based sustainable intensification practices led to a 60-90% increase in water infiltration and a 10-50% increase in maize yields in Malawi. In Ethiopia, crop incomes nearly doubled with crop diversification, reduced tillage and improved varieties, compared to using only one of these practices.
According to research from Stanford University, agricultural intensification has avoided emissions of up to 161 gigatons of carbon from 1961 to 2005. CIMMYT research shows that India could cut nearly 18% of agricultural greenhouse gas emissions through sustainable intensification practices that reduce fertilizer consumption, improve water management and eliminate residue burning. Zero-tillage wheat can cut farm-related greenhouse gas emissions by more than 75% in India and is 10-20% more profitable on average than burning rice straw and sowing wheat using conventional tillage.
A CIMMYT study in Science shows that thousands of wheat farmers in northern India could increase their profits if they stop burning their rice straw residue and adopt no-till practices, which could also cut farm-related greenhouse gas emissions by as much as 78% and lower air pollution. This research and related work to promote no-till Happy Seeders led to a 2018 policy from the government of India to stop farmers from burning residue, including a $166 million subsidy to promote mechanization to manage crop residues within fields.
In light of this evidence, CIMMYT continues to work with stakeholders all along the value chain — from farmers to national agricultural research organizations and companies — to promote and scale the adoption of practices leading to sustainable intensification.
Cover photo: Irrigated fields under conservation agriculture at CIMMYT’s CENEB experiment station near Ciudad Obregón, Sonora, northern Mexico. (Photo: CIMMYT)
Incoming CIMMYT Global Wheat Program director Alison Bentley speaks at Borlaug Global Rust Initiative Workshop. (Photo: CIMMYT)
Alison Bentley, who will be joining the International Maize and Wheat Improvement Center (CIMMYT) next month as director of the Global Wheat Program and the CGIAR Research Program on Wheat, joined wheat research colleagues at the Borlaug Global Rust Initiative Technical Workshop last week to introduce herself and offer her perspective on current prospects for wheat research.
Bentley, who currently serves as director of Genetics and Breeding at the National Institute of Agricultural Botany in the UK, emphasized the efforts of CIMMYT and partner scientists in the Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG) project.
“AGG is unique, and it’s something that’s really close to my heart in harnessing innovations and deploying them in breeding to deliver genetic gains,” she said.
Bentley gave workshop attendees a sneak preview of new speed breeding facilities in CIMMYT’s Toluca experimental station, which will help wheat breeders reduce cycle time, saving costs and getting high yielding, improved varieties tested and in farmers’ fields more quickly.
“There has never been a more exciting time to be involved in wheat research and breeding,” she told the gathering.
See Alison Bentley’s full presentation from the BGRI Technical Workshop below.
Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG) is a 5-year project that brings together partners in the global science community and in national agricultural research and extension systems to accelerate the development of higher-yielding varieties of maize and wheat — two of the world’s most important staple crops. Funded by the Bill & Melinda Gates Foundation, the UK Foreign, Commonwealth & Development Office (FCDO), the U.S. Agency for International Development (USAID) and the Foundation for Food and Agriculture Research (FFAR), AGG fuses innovative methods that improve breeding efficiency and precision to produce and deliver high-yielding varieties that are climate-resilient, pest- and disease-resistant, highly nutritious, and targeted to farmers’ specific needs.
Rural women in Nepal significantly contribute to food security, and when they are empowered, they can create avenues for agricultural growth. As seed producers are often disadvantaged in terms of accessing advanced agricultural knowledge and seed production skills, one opportunity for growth is strengthening the capacity of women seed producers.
“In more than 80% of households in Sindhupalchowk district, women have the final say on the selection of maize variety,” said D.B. Bhandari, managing director of Hairyali Community Seed Company (HCSC). “This urged me to engage women in seed production of preferred maize varieties for the mid-hills.”
HCSC, a partner company of the Nepal Seed and Fertilizer (NSAF) project implemented by the International Maize and Wheat Improvement Center (CIMMYT), is working to improve the business literacy of rural women to support their involvement in seed production and marketing of maize, wheat and rice seeds in Sindhupalchowk district, Bagmati province, Nepal.
Seed producers attend an orientation on the production and marketing of hybrid seed. (Photo: Dharma Dawadi/CIMMYT)
A path to empowerment and income
Access to agricultural inputs such as seed and fertilizer is challenging in Thulosirubari village due to its rural location and absence of agrodealers or nearby markets. Progressive farmers Parbati Gautam and Kamala Gautam, who grew up in the village in a family that has cultivated maize for generations and now grow maize, rice, millet and vegetables, found a solution. They decided to establish a cooperative —Thulosirubari Mahila Krishi Sahakari Sanstha — that not only eases the supply of seed for farmers in their village but also engages in seed production. The cooperative has 45 female members so far.
In coordination with HCSC and the Government of Nepal’s Prime Minister Agriculture Modernization Project (PMAMP), orientation programs and women-only trainings were designed and organized by the NSAF project so farmers could boost their seed production efficiency and profitability at the grassroots level. The partnership between CIMMYT, HCSC and PMAMP provided technical and financial support to these groups, improved their entrepreneurship skills and business literacy, and created marketing linkages between the farmers and buyers. Thirty-five women were trained in the use of good agricultural practices in quality seed production and marketing of hybrid maize, rice and tomato seeds. HCSC supported the women with male and female lines of hybrid maize — Khumal hybrid-2 — to produce first generation seeds and build their skills on estimating ratios for sowing seeds, balanced fertilizer application, weeding, rouging and detasseling.
“I am so happy to learn about the importance of having different male and female lines and how to maintain their quality for crossing to produce first generation of hybrid maize seeds,” Kamala Gautam said.
After getting the required training and technical support, seven farmers from the cooperative, including Kamala and Parbati, collectively produced 1.1 mt of Khumal hybrid-2 with the value of $2,514, which was sold to HCSC in 2019. As the cooperative is a contract seed producer for HCSC, the women have market assurance and do not worry where and how to sell their seed.
“My husband and I are not educated,” Parbati Gautam explained. “However, I was able to sell the hybrid maize seed then use the money to buy decent clothes and offer a better education to my two daughters and son.”
A woman stands in her rice seed production field in Nepal. (Photo: Mohan Mahato/CIMMYT)
Women empowering women
Parbati Gautam has served as chairperson at the cooperative for eight years, where she has mentored other seed producers. Based on her experience, women who have access to information and seed production technologies tend to have better crop yields and make informed decisions to increase their incomes and livelihoods.
According to Bhandari, farmers’ preferences are gradually shifting from local to hybrid varieties which offer better yields, early maturity and resilience to the effects of climate change. Parbati and Kamala Gautam confirm this, sharing that hybrid seed production provides 4-5 times more monetary value per kilogram of seed than that of grain.
“Although the cost of parent lines is expensive for seed production, improved farming technology ensures better quality seeds, higher yields and attractive farm business opportunities,” Parbati Gautam explained.
Since 2017, NSAF project researchers have been working to establish linkages with partner seed companies for seed marketing. Altogether, about 300 mt of maize and rice seed was produced by women farmers engaged in the project with the value of $112,000, and 80 percent of this seed was sold to three private seed companies including HCSC. In 2019, the NSAF project team established partnerships with an additional three cooperatives in Banke, Dang and Sindhupalchowk districts, where over 800 women are members.
The project’s engagement of women’s seed producer groups is an example of an inclusive seed business model where farmers decide what to grow and how to sell. This intervention can be piloted in other parts of Nepal where women account for over 60 percent of the rural farming community. Targeted and sustained interventions to increase women’s business agility, technical capacity in quality seed production, and market linkages will help boost productivity at household level and the country at large.
The study identified two key explanations for the oversight. The first is that many cereal crops with varying nutritional qualities are indiscriminately grouped under the broad category of “staples.”
A second problem lies in the fact that cereals are usually considered to be a major source of dietary energy alone. However, reducing nutritional attributes to macro- and micro-nutrients misses other beneficial elements of cereals known as “bioactive food components.” These include carotenoids, flavonoids, and polyphenols, and compounds that comprise dietary fiber.
“Most whole grain cereals provide differing amounts of proteins, fats, minerals and vitamins, in addition to being important sources of dietary energy,” said Jason Donovan, a senior economist at the International Maize and Wheat Improvement Center (CIMMYT) and co-author of the paper published in Food Policy.
“Only relative to other ‘nutrient-rich’ foodstuffs can cereals be described as ‘nutrient-poor’.”
In the paper, entitled Agri-nutrition research: Revisiting the contribution of maize and wheat to human nutrition and health, the authors called on researchers and policymakers to embrace the multiple dietary components of cereals in addressing under- and over-nutrition, micronutrient deficiencies and the growing global problem of non-communicable diseases.
“Through increasing the availability of, and access to, healthy foods derived from cereals, we can better address the growing triple burden of malnutrition that many countries are facing,” said Olaf Erenstein, co-author and director of CIMMYT’s Socioeconomics program.
“To feed the world within planetary boundaries, current intakes of whole grain foods should more than double and address tricky issues like the current over-processing, to make the most of the nutrition potential of maize and wheat.”
While some carbohydrates can create a glycemic response that has negative effects on diabetes and obesity, dietary fiber in cereals comprises carbohydrates that are fermented in the large intestine with largely positive metabolic and health effects.
In addition, the naturally-occurring compounds found in maize and wheat can be enhanced through conventional breeding, genomic selection and bio- and industrial-fortification to offer enriched levels of beneficial components.
For example, scientists at CIMMYT have worked on new maize and wheat varieties with additional levels of vitamin A and zinc to help address some of the nutritional deficiencies found worldwide. Researchers are also improving how cereals are produced, processed, and stored to increase productivity and improve food safety while maintaining their nutritional benefits.
One of challenges in maximizing the nutritional benefit of cereal-based foods in diets is that the processing of grains often causes substantial losses of essential vitamins and minerals. Meanwhile, manufacturing industries create ultra-processed foods that often contain noxious qualities and components, which contribute directly to the significant and increasing global health and economic costs of non-communicable diseases.
“If we are to end hunger by delivering healthy, diverse and nutritional diets in the next decade, we need a broader and more nuanced understanding of the nutritional and health-promoting value of diverse foods, including cereals,” added Nigel Poole, co-author and Professor of International Development at SOAS University, London.
“Cereals and so-called ‘nutrient-rich’ foods are complementary in agri-nutrition, both of which require additional research, resources and attention so that one does not replace the other.”
The International Maize and What Improvement Center (CIMMYT) is the global leader in publicly-funded maize and wheat research and related farming systems. Headquartered near Mexico City, CIMMYT works with hundreds of partners throughout the developing world to sustainably increase the productivity of maize and wheat cropping systems, thus improving global food security and reducing poverty. CIMMYT is a member of the CGIAR System and leads the CGIAR programs on Maize and Wheat and the Excellence in Breeding Platform. The Center receives support from national governments, foundations, development banks and other public and private agencies. For more information visit staging.cimmyt.org
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