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饮料的营养密度与气候影响的关系。

Nutrient density of beverages in relation to climate impact.

机构信息

Unit for Clinical Nutrition and Metabolism, Department of Public Health and Caring Sciences, Uppsala University, Uppsala, Sweden.

出版信息

Food Nutr Res. 2010 Aug 23;54:5170. doi: 10.3402/fnr.v54i0.5170.

DOI:10.3402/fnr.v54i0.5170
PMID:20806074
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2924839/
Abstract

The food chain contributes to a substantial part of greenhouse gas (GHG) emissions and growing evidence points to the urgent need to reduce GHGs emissions worldwide. Among suggestions were proposals to alter food consumption patterns by replacing animal foods with more plant-based foods. However, the nutritional dimensions of changing consumption patterns to lower GHG emissions still remains relatively unexplored. This study is the first to estimate the composite nutrient density, expressed as percentage of Nordic Nutrition Recommendations (NNR) for 21 essential nutrients, in relation to cost in GHG emissions of the production from a life cycle perspective, expressed in grams of CO(2)-equivalents, using an index called the Nutrient Density to Climate Impact (NDCI) index. The NDCI index was calculated for milk, soft drink, orange juice, beer, wine, bottled carbonated water, soy drink, and oat drink. Due to low-nutrient density, the NDCI index was 0 for carbonated water, soft drink, and beer and below 0.1 for red wine and oat drink. The NDCI index was similar for orange juice (0.28) and soy drink (0.25). Due to a very high-nutrient density, the NDCI index for milk was substantially higher (0.54) than for the other beverages. Future discussion on how changes in food consumption patterns might help avert climate change need to take both GHG emission and nutrient density of foods and beverages into account.

摘要

食物链是温室气体(GHG)排放的重要贡献者,越来越多的证据表明,减少全球温室气体排放已刻不容缓。其中建议包括通过用更多植物性食物替代动物性食物来改变食物消费模式。然而,改变消费模式以降低温室气体排放的营养方面仍然相对未被探索。本研究首次从生命周期角度,使用一种称为营养密度对气候影响(NDCI)指数的指标,估计了复合营养素密度,以百分比表示 21 种必需营养素与成本相关的温室气体排放,以克 CO2 当量表示。NDCI 指数是针对牛奶、软饮料、橙汁、啤酒、葡萄酒、瓶装碳酸水、大豆饮料和燕麦饮料计算的。由于低营养密度,碳酸水、软饮料和啤酒的 NDCI 指数为 0,红葡萄酒和燕麦饮料的 NDCI 指数低于 0.1。橙汁(0.28)和大豆饮料(0.25)的 NDCI 指数相似。由于极高的营养密度,牛奶的 NDCI 指数(0.54)远高于其他饮料。未来关于改变食物消费模式如何有助于避免气候变化的讨论需要考虑食物和饮料的温室气体排放和营养密度。

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