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Journal of Integrative Agriculture  2021, Vol. 20 Issue (6): 1727-1729    DOI: 10.1016/S2095-3119(20)63299-3
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Low glycemic index: The next target for rice production in China?
HUANG Min, HU Li-qin
Crop and Environment Research Center for Human Health, College of Agronomy, Hunan Agricultural University, Changsha 410128, P.R.China
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摘要  

中国65%人口以大米为主食。随着生活水平的不断提高,国人对优质食味(低直链淀粉含量)大米的消费和需求不断增加。但大米直链淀粉含量越低,其血糖指数往往越高,对糖尿病等慢性非传染性疾病的防治就越不利。基于中国已成为世界上糖尿病人最多的国家,我们呼吁应将低血糖指数作为水稻生产的一个目标。




Abstract  China has 22% of the world’s population but only 7% of the world’s arable land.  Food security has been a chief mission of the Chinese state since the beginning of the dynastic era and remains a primary objective in the early 21st century.  As a result, high yield has been the first priority of farmers, researchers and agricultural agencies in China for a long time.
    Rice is the most important food crop in China, feeding about 65% of the national population.  Rice self-sufficiency has been achieved in China by increasing grain yields by more than 50% since 1980, and this trend is likely to be sustained assuming current yield and consumption trajectories without reduction in production area (Deng et al. 2019).
    As living standards improve, the demand for high quality rice, especially good taste rice, increases in China.  In general, rice with low amylose content and soft texture is preferred by Chinese rice consumers.  This preference has driven considerable changes in rice production of China: (1) in single-season rice cropping regions such as Jiangsu and Heilongjiang provinces, the planting area of soft japonica rice with low amylose content (<15%) has increased substantially while that of non-soft japonica rice with relatively high amylose content has decreased considerably (Zhu et al. 2015); (2) in single- and double-season (early and late seasons) rice mixed cropping regions such as Hunan and Jiangxi provinces, the planting area of early-season indica rice, which is dominated by cultivars with high amylose content (Yin et al. 2020), has decreased sharply (Peng 2016), whereas the planting area of single- and late-season indica rice with moderate to low amylose contents has increased significantly.  Increasing eating quality of rice has also been a focus for Chinese rice researchers and agricultural agencies. New tasty (soft texture) indica and japonica rice cultivars have been increasingly developed and grown in China to cater to consumer preferences (Zeng et al. 2019).
    Improved living standards are also driving up the demand for healthy food in China.  However, rice is generally categorized as a food with high glycemic index (GI).  There is an evidence that rice consumption is significanlty positively associated with the increase in risk of type II diabetes, especially in Asian populations including Chinese (Hu et al. 2012).  Based on the dose-response relation between rice intake and relative risk of type II diabetes plotted by Hu et al. (2012), Song et al. (2017) found that the relative risk of type II diabetes was significantly elevated above 1.00 in China under the current rice intake, i.e., 213 and 256 g d–1 for women and men, respectively.  In addition, China currently has the highest number of people with diabetes (mainly type II diabetes) in the world, with 114 million or 12% of Chinese adults being diagnosed with diabetes and an additional 493 million with pre-diabetes (Xu et al. 2013).  It is well known that diet management is very important for diabetes care (Sami et al. 2017).  Choosing low-GI foods in place of high-GI foods is a clinically useful way to control glycemic levels in people with diabetes (Brand-Miller et al. 2003).  Therefore, it is meaningful and urgent to produce low-GI rice in China to reduce risk of type II diabetes.  In this regard, it has been found that there is a large variability in GI among rice cultivars.  For example, Fitzgerald et al. (2011) reported that the GI of cooked rice ranged from 48 to 92 in a set of 235 cultivars.
    Our concern is that the current rapid development of tasty rice with soft texture (low amylose content) may increase rather than reduce the risk of type II diabetes in China, because the lower the amylose content of rice, the lower the resistant starch contents (Rahman et al. 2007), the less the resistance to digestion (Hu et al. 2004), and the higher the GI (Fitzgerald et al. 2011).  This concern can be supported by a human diet study of Ohtsubo et al. (2016), who observed that a more drastic increase of postprandial blood glucose occurred in the case of eating low-amylose rice than in the case of eating high-amylose rice and thus concluded that the high-amylose rice is promising for the purpose of diabetes prevention.  Our concern is also supported by a population-based study of 3 918 Chinese adults aged 23–69 years (Cheng et al. 2017), which showed that the consumption of rice with high GI was detrimentally associated with glucose homeostasis and suggested that the preferred choice of rice with lower GI should be advocated.  These also highlight that the cultivar change should be included when modeling the risk of type II diabetes associated with rice intake.
    There is no doubt that low-GI rice with high amylose and resistant starch contents is not preferred by most Chinese consumers in the terms of palatability.  However, in the age of increasing prevalence of non-communicable diseases, most rice consumers are expected to choose health over taste.  Therefore, we appeal that China should begin to consider human health as a target for rice production.  Taken into considerations that (1) GI of rice is not only closely related to its amylose and resistance starch contents but also affected by its other starch traits (e.g., starch gelatinization and retrogradation properties, the particle size of starch granule, the ratio of amylose to amylopectin, the crystallite structure of amylopectin, the starch resistance against enzymatic hydrolysis, and the interactions of starch with other components) and external factors such as cooking conditions (Frei et al. 2003; Rahman et al. 2007; Kaur et al. 2016); and (2) GI of foods and some starch traits such as the resistance starch contents are different depending on measurement method (Brand-Miller and Holt 2004; Walter et al. 2005), we therefore suggest promoting collaborative studies among researchers from various disciplines (crop science, food science and public health) to permit a full understanding of low-GI rice (Fig. 1).  The collaborative studies are not difficult to arrange given that China has established a batch of collaborative innovation centers at national and local levels and has accumulated a wealth of experience.  The studies can start by (1) investigating the digestive properties and glycemic impact of existing rice cultivars with different grain physicochemical characteristics across a wide range of environments, crop management practices and cooking conditions; and (2) considering the minimal extent of desirable palatability for the development of low-GI rice cultivars with high amylose and resistance starch contents in breeding programs.  In addition, it is also important to facilitate the collaboration among academy, government and business to enhance the consumer acceptance of low-GI rice (Jones and Jew 2007).  These works will provide useful information to guide the evaluation, production and promotion of healthy rice in China in the near future.
Received: 24 April 2020   Accepted:
Fund: This work was supported by the National Key R&D Program of China (2016YFD0300509).
Corresponding Authors:  Correspondence HUANG Min, E-mail: mhuang@hunau.edu.cn    

Cite this article: 

HUANG Min, HU Li-qin. 2021. Low glycemic index: The next target for rice production in China?. Journal of Integrative Agriculture, 20(6): 1727-1729.

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