Biofortification: Future Challenges for a Newly Emerging Technology to Improve Nutrition Security Sustainably

IF 3.8 Q2 NUTRITION & DIETETICS
Howarth Bouis , Jennifer Foley , Keith Lividini , Jaya Jumrani , Russell Reinke , Dominique Van Der Straeten , Ronan Zagado , Erick Boy , Lynn R Brown , Bho Mudyahoto , Richard Alioma , Munawar Hussain , Wolfgang H Pfeiffer
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Abstract

Biofortification was coined as a term to define a plant breeding strategy to increase the micronutrient content of staple food crops to reduce the burden of micronutrient deficiencies in low- and middle-income countries. In 2003, the HarvestPlus program, based in the centers comprising the Consultative Group on International Agricultural Research, was initiated to implement the biofortification strategy. This article discusses what has been achieved, what has been learned, and the key challenges to embed biofortification in food systems and to expand its impact. Cost-effectiveness is key to the biofortification strategy. Biofortification piggybacks on the agronomically superior varieties being developed at agricultural research centers. Central plant breeding research discoveries can be spread globally. Farmers have every motivation to adopt the latest high-yielding, high profit crops. High productivity leads to lower food prices. As a consequence, consumers can increase their mineral and vitamin intakes at no additional cost by substituting biofortified staple foods 1-for-1 for nonbiofortified staple foods. After 20 years of investment, biofortified staple food crops are being produced by farmers in over 40 countries and are eaten by hundreds of millions of people. Published nutrition trials have shown nutrient-rich crops to be efficacious. The biofortification strategy is now recognized by the international nutrition community as one effective approach among several interventions needed to reduce micronutrient deficiencies. This is a promising beginning. However, biofortification is still a newly emerging technology. A limitation of biofortification as implemented to date is that densities of single nutrients have been increased in given staple food crops. To reach a higher trajectory, the impacts of biofortification can be multiplied several-fold using genetic engineering and other advanced crop development techniques to combine multiple-nutrient densities with climate-smart traits.
生物强化:可持续改善营养安全的新兴技术的未来挑战
生物强化(Biofortification)是一个术语,用来定义提高主食作物微量营养素含量的植物育种战略,以减轻中低收入国家微量营养素缺乏症的负担。2003 年,在国际农业研究磋商组织(Consultative Group on International Agricultural Research)各中心的基础上,启动了 "丰收计划"(HarvestPlus),以实施生物强化战略。本文讨论了在将生物强化纳入粮食系统并扩大其影响方面所取得的成就、汲取的经验教训以及面临的主要挑战。成本效益是生物强化战略的关键。生物强化利用了农业研究中心正在开发的农艺优良品种。中心的植物育种研究成果可以在全球范围内推广。农民完全有动力采用最新的高产、高利润作物。高生产率可降低粮食价格。因此,消费者可以通过以生物强化主食替代非生物强化主食的方式,增加矿物质和维生素的摄入量,而无需额外成本。经过 20 年的投资,40 多个国家的农民正在生产生物强化主粮作物,数亿人正在食用这些作物。已公布的营养试验表明,营养丰富的作物具有功效。生物强化战略现已被国际营养界公认为减少微量营养素缺乏症所需的几种干预措施中的一种有效方法。这是一个充满希望的开端。然而,生物强化仍是一项新兴技术。迄今为止实施的生物强化技术的局限性在于提高了特定主食作物中单一营养素的密度。为了实现更高的发展目标,可以利用基因工程和其他先进的作物开发技术,将多种营养素密度与气候智能特性结合起来,使生物强化的影响翻几番。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Current Developments in Nutrition
Current Developments in Nutrition NUTRITION & DIETETICS-
CiteScore
5.30
自引率
4.20%
发文量
1327
审稿时长
8 weeks
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