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Meat and milk intake in the rice-based Korean diet: impact on cancer and metabolic syndrome

Published online by Cambridge University Press:  15 March 2016

Shinyoung Jun
Affiliation:
Graduate School of Public Health, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, Korea
Kyungho Ha
Affiliation:
Graduate School of Public Health, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, Korea
Sangwon Chung
Affiliation:
Graduate School of Public Health, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, Korea
Hyojee Joung*
Affiliation:
Graduate School of Public Health, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, Korea Institute of Health and Environment, Seoul National University, Seoul, Korea
*
*Corresponding author: H. Joung, fax +82 2 883 2832, email [email protected]
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Abstract

Over a few decades, Korean diet has changed from traditional diet, mainly composed of rice and vegetables, to Westernised diet rich, in meat and milk, along with the economic development and globalisation. Increasing prevalence of diet-related chronic diseases such as cancer and metabolic syndrome (MetS) is becoming a heavy burden to society and requires further attention. In this review, the association of meat and milk consumption with cancer and MetS among Koreans was discussed. Previous meta-analyses showed that meat intake was positively associated with increased risk of cancers, especially colon, as well as obesity and type 2 diabetes mellitus, and that the intake of milk and dairy products was negatively associated with colorectal cancer, obesity, and type 2 diabetes mellitus, based on studies conducted mostly in Western countries. In Korea and other Asian countries, the association of meat and milk intake with cancers were inconclusive and varied by types of cancers. Conversely, milk intake was negatively associated with MetS risk as reported in Western countries. The difference in results between Korea and Western countries might come from the differences in dietary patterns and study designs. Most Koreans still maintain traditional dietary pattern, although rapid change towards Westernised diet is underway among the younger age group. Randomised clinical trials or prospective cohort studies with consideration of combined effects of various dietary factors in Korea and other Asian countries are needed to elucidate the impact of meat and milk or related dietary patterns in their diet.

Type
Conference on ‘The future of animal products in the human diet: health and environmental concerns’
Copyright
Copyright © The Authors 2016 

In recent decades, diet transitions have occurred in Asian countries along with the economic development and globalisation. Among these countries, South Korea experienced economic growth earlier than did most Asian countries and has shown significant dietary changes from traditional rice-based diet to the so-called Westernised diet( Reference Kim, Moon and Popkin 1 Reference Kang, Joung and Lim 4 ). Traditional Korean diet was composed mainly of rice and vegetables and very little meat and milk. Even though Koreans still maintain considerable part of rice-based diet, meat and milk consumption has increased dramatically and rice consumption has decreased among Koreans( 5 ).

Concurrently, the burden of non-communicable diseases such as metabolic syndrome (MetS) and cancer has rapidly increased in Korea. Cancer has been the leading cause of death since 1983, and CVD and type 2 diabetes related to MetS also have been major causes of death( 6 ). These chronic diseases are well known to be associated with diet; many epidemiological studies have reported that meat consumption increased the risk of metabolic diseases and cancer( Reference Song, Lu and Yin 7 Reference Micha, Michas and Mozaffarian 11 ), while milk consumption reduced the risk( Reference Aune, Lau and Chan 12 Reference Aune, Norat and Romundstad 16 ).

Change of diet, especially increased consumption of meat and milk, seems closely related to higher rates of chronic diseases among Koreans. However, the impact of higher meat and milk intake on MetS and cancer can be somewhat different among Koreans from that among Western populations due to the combined effects of other dietary factors related to traditional Korean diet. Therefore, more extensive understanding of the association between meat and milk consumption and MetS and cancer among Koreans is needed to provide important insights for chronic disease prevention in Korea and also in other Asian countries which have rice-based dietary patterns. In the present paper, we aimed to discuss the association of meat and milk consumption with MetS and cancer among Koreans.

Change of dietary intake and disease pattern among Koreans

Change of dietary intake

Over the past several decades, Korean diet has undergone considerable changes. Several sources of data can be used to examine the change of diet. One such source is the food balance sheet. The amount of rice supplied per person was 213·0 g/d in 2013, 41 % decrease from that in 1980. Meanwhile, the amount of meat supplied per person was 134·8 g/d in 2013, 7 and 256 % increase from those in 2012 and 1980, respectively. The supply of milk and dairy products also increased from 29·5 g per person daily in 1980 to 168·2 g/d in 2013, an increment of 470 %( 17 , 18 ).

Most of the information on food and nutrient intake was obtained from the National Nutrition Survey (1969–1995) and succeeding Korea National Health and Nutrition Examination Survey (1998–present). Based on these data, the proportion of animal product in Korean diet was under 10 % until the mid-1970s but increased to 21 % in 2013. Meat intake increased dramatically, 6·6 g in 1969, 67·8 g in 1995 and 105·0 g in 2013. Milk intake was under 10 g until 1981 and increased rapidly from the mid-1980s and is still gradually increasing, 79·7 g in 1998 and 111·4 g in 2013. However, rice intake has continuously decreased( 5 , 19 ) (Fig. 1).

Fig. 1. (Colour online) Secular trend of food intake among Koreans. Grains (), Meats (), Dairy products (), percentage of animal products (shaded). Data are from National Nutrition Survey (1969–1995), Korea National Health and Nutrition Examination Survey (1998–2013)( 5 ).

The change in the composition of food consumption has resulted in significant change of nutrient intake. Fat intake increased from 16·9 g in 1969 to 47·7 g in 2013. With respect to calcium intake, it moderately increased from 444 mg in 1969 to 506·8 mg in 2013. However, carbohydrate intake gradually decreased from 423 g in 1969 to 313·2 g in 2013 (Fig. 2). In addition, in 2013, more than half the population took vitamin C and calcium less than the estimated average requirement in almost every age group, and a high percentage of the elderly had vitamin A and riboflavin less than the estimated average requirement( 5 ).

Fig. 2. (Colour online) Secular trend of nutrient intake among Koreans. Energy (), Fat (), Carbohydrates (), Calcium (). Data are from National Nutrition Survey (1969–1995), Korea National Health and Nutrition Examination Survey (1998–2013)( 5 ).

The aforementioned change was identified as diet transition from a traditional Korean diet that mainly consisted of rice and vegetables to a Westernised diet abundant in meat and milk in previous studies( Reference Kim, Moon and Popkin 1 Reference Song, Joung and Engelhardt 3 ). Kang et al. reported that the proportion of traditional dietary pattern was decreased over time and was less among the younger generation than in the older generation( Reference Kang, Joung and Lim 4 ).

Change of the status of metabolic syndrome and cancer

In addition to diet transition, a shift in the pattern of diseases towards non-communicable diseases, such as cancer and MetS has occurred in Korea. Based on the Korea National Cancer Incidence Database, overall cancer incidence rate per 100 000 was 445·3 in 2012 which increased by 3·3 % annually from 1999 to 2012 (Fig. 3). Data from Statistics Korea indicated that cancer became the leading cause of deaths, responsible for one in four deaths, in 2012. Lung, liver, stomach and colon/rectum cancers were the main causes of cancer death. Heart disease, diabetes mellitus and hypertensive diseases associated with MetS were also leading causes of death in Korea, accounting for approximately 16 % of all deaths( Reference Jung, Won and Kong 20 ). Prevalence of MetS in Korea was 24·9 % in 1998 and increased to 31·3 % in 2007 (Fig. 4)( Reference Lim, Shin and Song 21 ).

Fig. 3. (Colour online) Secular trend of cancer incidence among Koreans. Data are taken from Jung et al.( Reference Jung, Won and Kong 20 )

Fig. 4. (Colour online) Secular trend of metabolic syndrome prevalence among Koreans. Data are taken from Lim et al.( Reference Lim, Shin and Song 21 )

Association of meat and milk consumption with cancer and metabolic syndrome

Meat and milk consumption and cancer and metabolic syndrome risk based on the results from meta-analyses

A joint report by the World Cancer Research Fund and the American Institute for Cancer Research recently concluded that there is convincing evidence on the association between red or processed meat and colorectal cancer, ‘limited to suggestive’ evidence on the association between red meat and cancer of oesophagus, lung, pancreas and endometrium; and between processed meat and cancer of oesophagus, lung, stomach and prostate( 22 ). Meta-analyses of cohort and case–control studies for the association between red meat consumption and stomach cancer risk showed that increased consumption of red meat could be a risk factor for gastric cancer( Reference Song, Lu and Yin 7 ) and breast cancer( Reference Guo, Wei and Zhan 8 ). In addition, another meta-analysis of prospective studies reported the significant association between beef consumption and increased risk of colorectal cancer and colon cancer, but no association between pork or poultry and the risk of colorectal adenomas or cancer( Reference Carr, Walter and Brenner 9 ). Poultry intake was rather associated with reduced risk of colorectal cancer( Reference Shi, Yu and Zeng 23 ).

Meat consumption has also been considered as a major risk factor for MetS. Recently, several meta-analyses showed significant associations between red meat or processed meat intake and MetS risk factors or related diseases. Meta-analysis of prospective cohorts( Reference Micha, Michas and Mozaffarian 11 ) reported that consumption of processed meats was associated with 42 % higher risk of CHD and 51 % higher risk of diabetes. In addition, consumption of unprocessed red meats was associated with 19 % higher risk of diabetes, but no risk of CHD( Reference Micha, Michas and Mozaffarian 11 ). A meta-analysis of observational studies by Rouhani et al.( Reference Rouhani, Salehi-Abargouei and Surkan 10 ) showed consumption of higher amount of red and processed meats increased the risk of obesity.

Dairy consumption has long been thought to play a role in cancer development. Previous meta-analyses noted the association between milk consumption and cancer at specific sites. A meta-analysis of prospective cohort studies on dairy consumption and the risk of breast cancer( Reference Dong, Zhang and He 13 ) reported the decreased risk of breast cancer (relative risk (RR) 0·85, 95% CI 0·76, 0·95). Significant dose–response relationship of total dairy food, except milk, intake with breast cancer risk was also reported( Reference Dong, Zhang and He 13 ). For colorectal cancer RR was 0·91 (CI 0·85, 0·94) per 200 g/d of milk intake and 0·83 (CI 0·78, 0·88) per 400 g/d of total dairy products by a meta-analysis of cohort( Reference Aune, Lau and Chan 12 ). Meanwhile, a meta-analysis on dairy consumption and gastric cancer risk( Reference Guo, Shan and Ren 24 ) including twenty-three epidemiologic studies suggested that total dairy food, except milk, might be associated with a reduced risk of gastric cancer.

A series of meta-analyses have consistently suggested that increased milk intakes are associated with reduced risk of MetS and MetS-related diseases. A meta-analysis of randomised controlled clinical trials( Reference Abargouei, Janghorbani and Salehi-Marzijarani 14 ) examined the effect of dairy consumption on weight and body composition. Dairy consumption led to significantly greater reduction in fat mass and waist circumference and the effect was much greater with energy restriction. Another meta-analysis of randomised controlled trials( Reference Chen, Pan and Malik 25 ) also reported beneficial effects of dairy consumption on body weight and fat loss under energy restriction, but the effects were not consistent in long-term or ad libitum studies. In addition, inverse association between low-fat and fluid dairy food consumption and elevated blood pressure was found in a meta-analysis of cohort studies( Reference Ralston, Lee and Truby 15 ). Aune et al.( Reference Aune, Norat and Romundstad 16 ) focused on dairy products and type 2 diabetes and concluded that there was an inverse association between consumption of total dairy product and low-fat dairy product, and risk of type 2 diabetes.

Association of meat and milk consumption with cancer and metabolic syndrome in Korea and other Asian countries

From previous meta-analyses, we could conclude that excessive intake of red meat can result in elevated risk of cancer and MetS, whereas high intake of milk and its product is associated with the reduced risk of cancer and MetS. However, because most previous studies on the health effect of meat and milk were conducted in Western populations, there is little understanding on the association between meat and milk intake, and cancer and MetS in Asians. To elucidate the impact of meat and milk consumption on cancer and MetS, epidemiological studies conducted in Asia, including Korea were further reviewed.

The level of meat intake was very low in many Asian populations who had rice-based dietary pattern, but it began to rise rapidly since the late 20th century. Although meat consumption is still relatively low in Asians compared with Western populations, it requires more attention. Meat is a source of not only protein and various vitamins and minerals, but also SFA( Reference Kim, Kim and Ahn 26 ) which are well known to be a major risk factor for various chronic diseases( Reference Riccardi, Giacco and Rivellese 27 , Reference Sieri, Krogh and Ferrari 28 ). Moreover, haem iron and non-haem iron, or some carcinogenic compounds such as heterocyclic amines and polycyclic aromatic hydrocarbons in meat are suspected to increase cancer risk( Reference Fonseca-Nunes, Jakszyn and Agudo 29 , Reference Knize, Salmon and Pais 30 ).

As in studies involving Western populations, consuming high amount of red meat was reported as a significant risk factor for cancer by a recent Korean cohort study( Reference Wie, Cho and Kang 31 ). Red meat, especially processed red meat, consumption was positively associated with overall cancer incidence in men. Korean males who ate red meat above the World Cancer Research Fund and the American Institute for Cancer Research recommended amount of 43 g/d had 41 % higher risk of overall cancer. Considering the recommended amount of 43 g/d is smaller than one serving size for a Korean, this implies that even small amounts of red meat intake may increase the risk of cancer in Koreans. The researchers explained the reason why the association was significant only in men as that the mean intake of red meat and the percentage of individuals who consumed more than the recommendation were higher in men. Later, a case–control study among Korean adults( Reference Chun, Sohn and Song 32 ) added the evidence that red meat intake significantly increased risk for colorectal cancer incidence. However, there was a case–control study( Reference Kim, Chang and Kim 33 ) which examined the association of beef or pork intake with gastric cancer and reported insignificant results. Similarly, findings from studies among Chinese population varied. Red meat intake and preserved meat intake were risk factors for bladder cancer( Reference Isa, Xie and Hu 34 ), and fresh meat intake was a risk factor for lung cancer( Reference Shen, Chapman and He 35 ). However, consumption of salt-preserved meats was associated with reduced risk of lung cancer in China( Reference Shen, Chapman and He 35 ) (Table 1).

Table 1. Meat consumption and cancer in Korean and other Asian countries

I, incidence; OR, odds ratio; RR, relative risk; HR, hazard ratio; T, tertile.

*Values in parentheses are 95% CI.

Meat consumption seemed to increase the risk of MetS or its components in Asian countries. A series of observational studies among Chinese population demonstrated significant association between intake of red meat and excessive body fat, measured as abdominal obesity, high BMI, and overweight( Reference Wang, Zhang and Zhai 36 Reference Xu, Yin and Tong 38 ). A large cohort study of Japanese population( Reference Kurotani, Nanri and Goto 39 ) reported significant effect of red meat consumption on the development of type 2 diabetes. The associations of processed red meat intake or poultry intake with type 2 diabetes risk were not found in the same study. The impact of meat on MetS among Koreans was not revealed due to limited information. However, considering Asian populations share common characteristics in their diet, it would be reasonable to expect similar results with other Asians (Table 2).

Table 2. Meat consumption and metabolic syndrome in Korean and other Asian countries

P, prevalence; I, incidence; OR, odds ratio; Q, quartile.

*Values in parentheses are 95% CI.

Milk, like meat, has not been an important component of traditional diet in Korea and most Asian countries until the late 20th century. However, milk and dairy foods have now become a crucial part of Korean diet. It is widely recommended to increase milk and dairy food consumption as a good source of calcium and other nutrients. A number of studies conducted in Western countries reported milk and dairy products have health benefits on chronic disease prevention( Reference Aune, Lau and Chan 12 Reference Aune, Norat and Romundstad 16 ). Milk consumption of Koreans has rapidly increased since the 1980s, but the level of consumption is still relatively lower than that of Western countries. The proportion of people who drink milk less than one serving size daily was 84 %( Reference Lee and Joung 40 ) and of those who drink milk less than once per week was 34 %( 19 ) in Korea. The difference between frequent milk consumers and infrequent consumers seemed evident.

A substantial number of epidemiological studies aimed to verify the impact of milk on chronic disease risk in Korea and other Asian countries. In Korea, Kim et al.( Reference Kim, Chang and Kim 33 ) reported significant inverse association between milk and milk products and gastric cancer risk with case–control study design, whereas Chun et al.( Reference Chun, Sohn and Song 32 ) reported a positive association between milk intake and colorectal cancer risk with similar study design. In China, a case–control study on bladder cancer( Reference Isa, Xie and Hu 34 ) reported strong health benefits of dairy foods, and another case–control study demonstrated potential protective effects of milk intake on breast cancer( Reference Zhang, Ho and Fu 41 ). In Japan, a case–control study( Reference Mizoue, Kimura and Toyomura 42 ) found statistically significant inverse association between calcium and vitamin C intake and colorectal cancer, and potential inverse association between milk and other dairy food intake, and colorectal cancer risk. In a Japanese cohort study( Reference Matsumoto, Ishikawa and Nakamura 43 ), the associations with other cancers were unclear, except the association between increased butter and milk intake and deaths from hematopoietic neoplasm. Another cohort study focusing on prostate cancer( Reference Kurahashi, Inoue and Iwasaki 44 ) showed that higher milk intake resulted in higher risk of prostate cancer and suspected calcium and fatty acids as the causative agents (Table 3). The findings of these studies were inconsistent. The results from a few studies on milk and MetS conducted in Asia were consistent. A study using the third Korea National Health and Nutrition Examination Survey data( Reference Kwon, Lee and Park 45 ) showed that overweight adults who consume milk more frequently had significantly lower risk of MetS. The inverse relationship was supported by a study by Kim et al.( Reference Kim 46 ) which reported significant association between higher consumption of milk or yoghurt and lower risk of MetS based on the fifth Korea National Health and Nutrition Examination Survey data. The study also found the association between higher dairy food intake and lower risk of MetS components, namely abdominal obesity, high fasting glucose and low-HDL cholesterol level. Additionally, the prevalence of MetS was significantly lower in subjects with higher dairy foods. Furthermore, Shin et al.( Reference Shin, Yoon and Lee 47 ) analysed the data of middle-aged Koreans from Anseong and Ansan cohort and suggested that dairy product consumption might reduce the risk of MetS, especially abdominal obesity. In subjects who consumed milk and dairy products once daily, the risk of MetS reduced by about 21 and 25 %, respectively. Another study in Japan( Reference Akter, Kurotani and Nanri 48 ) revealed that among three types of dairy products classified by fat content, only full-fat dairy products had significant inverse relationship with fasting insulin and homeostasis model of insulin resistance index (Table 4).

Table 3. Milk consumption and cancer in Korean and other Asian countries

I, incidence; M, mortality; OR, odds ratio; RR, relative risk; HR, hazard ratio; T, tertile; Q, quartile.

*Values in parentheses are 95% CI.

Table 4. Milk consumption with metabolic syndrome in Korean and other Asian countries

I, incidence; P, prevalence; HR, hazard ratio; OR, odds ratio; Q, quartile; HOMA-IR, homeostasis model assessment of insulin resistance.

*Values in parentheses are 95% CI.

Potential impact of dietary pattern on the association between meat and milk consumption and cancer and metabolic syndrome

We could find slight difference between the associations found in Western countries and in Asian countries. The difference could be attributed to the fact that Asians consume much lower amounts of meat and milk than do Western populations and that Asians have rice-based dietary pattern distinct from Western diet. However, there is little information on the role of meat and milk in Asian populations with extensive consideration on dietary backgrounds. Therefore, the evaluation of the overall diet quality with dietary pattern analysis to capture the combined effects of various dietary factors on cancer and MetS in Asian populations can be useful to expand our understanding.

In Japan, the dietary patterns with high dairy foods, fruit and vegetables significantly decreased cancer risks in stomach, rectum and breast( Reference Pham, Fujino and Kikuchi 49 Reference Hirose, Matsuo and Iwata 51 ). However, the findings from the studies focused on the effect of dietary patterns with high animal food on various types of cancer were inconsistent( Reference Pham, Fujino and Kikuchi 49 Reference Hirose, Matsuo and Iwata 51 ). In a Chinese study, vegetable-rich dietary patterns were significantly associated with lower risks of liver and breast cancer and meat-rich dietary patterns were associated with higher risk of breast cancer( Reference Zhang, Ho and Fu 52 , Reference Zhang, Xiang and Li 53 ) (Table 5). The findings from epidemiologic studies conducted in Asian countries which have the rice-based dietary pattern might provide useful information that can be applied to Korean population. More studies focusing on dietary patterns and MetS among Asians have suggested that high intake of milk and dairy products were related to the decreased risk of MetS. Japanese subjects who usually had milk and yoghurt in their breakfast were less likely to have MetS and high blood pressure( Reference Akter, Kurotani and Nanri 48 ). Thai females who possessed the so-called healthy dietary pattern composed of high intakes of beans, fruits, soya milk and fish also had lower risk of MetS( Reference Aekplakorn, Satheannoppakao and Putwatana 54 ). Furthermore, Korean adults with dietary patterns abundant in vegetables, meats and dairy foods showed lower incidence of MetS compared with dietary patterns characterised by high intake of refined white rice and low intake of dairy foods( Reference Baik, Lee and Jun 55 ). Hong et al.( Reference Hong, Song and Lee 56 ) clearly demonstrated that ‘fruit and dairy’ pattern was significantly associated with reduced risk of MetS and its components, namely impaired fasting glucose, hypertriglyceridaemia. Interestingly, ‘alcohol and meat’ pattern which can be regarded as the Westernised dietary pattern was not associated with risk of MetS due to relatively low-fat intake even among subjects with ‘alcohol and meat’ pattern. In addition, ‘Korean traditional’ dietary pattern with high intake of soya sauce, refined grains and vegetables was associated with increased MetS risk, indicating the importance of adequate proportion among carbohydrate, protein and fat. However, another observational study involving Korean adults( Reference Song and Joung 57 ) reported ‘meat and alcohol’ pattern was associated with increased risk of elevated blood glucose, elevated serum TAG and elevated blood pressure compared with traditional Korean dietary pattern mainly of rice and kimchi( Reference He, Yang and Zhang 58 , Reference Arisawa, Uemura and Yamaguchi 59 ) (Table 6).

Table 5. Dietary patterns and cancer in Korean and other Asian countries

I, incidence; M, mortality; CI, confidence interval; HR, hazard ratio; OR, odds ratio; RR, relative risk; Q, quartile.

Table 6. Dietary patterns and metabolic syndrome (metS) in Korean and other Asian countries

I, incidence; P, prevalence; CI, confidence interval; OR, odds ratio; RR, relative risk; Q, quartile.

The findings of these studies suggest that the differences in dietary pattern can lead to different roles of meat and milk in diet among Korean, other Asians and Western populations. The unique finding from Korean studies was that even ‘meat and alcohol’ pattern, very likely to be Western-style diet, can be regarded as rice-based diet with fat intake relatively higher than other patterns, but still moderate compared with typical Western diet. Most Koreans still maintain traditional dietary pattern, being high in carbohydrate, low in fat and high proportion of plant foods, although rapid change towards Westernised diet is ongoing among the younger generation( Reference Kang, Joung and Lim 4 ). The differences in study designs might also have influenced the results. Randomised clinical trials or prospective cohort studies with consideration of combined effects of various dietary factors in Korea and other Asian countries will be helpful to elucidate the role of meat and milk or related dietary patterns in their diet.

Financial Support

None.

Conflict of Interest

None.

Authorship

H. J. formulated the research question and critically reviewed the manuscript; S. J. contributed to the collation of evidence and wrote the draft of the manuscript; K. H. and S. C. also contributed to the collation of evidence.

References

1. Kim, S, Moon, S & Popkin, BM (2000) The nutrition transition in South Korea. Am J Clin Nutr 71, 4453.Google Scholar
2. Lee, SK & Sobal, J (2003) Socio-economic, dietary, activity, nutrition and body weight transitions in South Korea. Public Health Nutr 6, 665674.Google Scholar
3. Song, Y, Joung, H, Engelhardt, K et al. (2005) Traditional v. modified dietary patterns and their influence on adolescents’ nutritional profile. Br J Nutr 93, 943949.CrossRefGoogle ScholarPubMed
4. Kang, M, Joung, H, Lim, JH et al. (2011) Secular trend in dietary patterns in a korean adult population, using the 1998, 2001, and 2005 Korean National Health and Nutrition Examination Survey. Korean J Nutr 44, 152161.Google Scholar
5. Korea Centers for Diseases Control and Prevention (2014) Korea Health Statistics 2013: Korea National Health and Nutrition Survey (KNHANES VI−1) Seoul: KCDC.Google Scholar
6. Statistics Korea (2015) Statistics Korea. Available at: http://kosis.kr (accessed July 2015).Google Scholar
7. Song, P, Lu, M, Yin, Q et al. (2014) Red meat consumption and stomach cancer risk: a meta-analysis. J Cancer Res Clin Oncol 140, 979992.Google Scholar
8. Guo, J, Wei, W & Zhan, L (2015) Red and processed meat intake and risk of breast cancer: a meta-analysis of prospective studies. Breast Cancer Res Treat 151, 191198.Google Scholar
9. Carr, PR, Walter, V, Brenner, H et al. (2015) Meat subtypes and their association with colorectal cancer: systematic review and meta-analysis. Int J Cancer 138, 293302.Google Scholar
10. Rouhani, MH, Salehi-Abargouei, A, Surkan, PJ et al. (2014) Is there a relationship between red or processed meat intake and obesity? A systematic review and meta-analysis of observational studies. Obes Rev 15, 740748.Google Scholar
11. Micha, R, Michas, G & Mozaffarian, D (2012) Unprocessed red and processed meats and risk of coronary artery disease and type 2 diabetes–an updated review of the evidence. Curr Atheroscler Rep 14, 515524.CrossRefGoogle ScholarPubMed
12. Aune, D, Lau, R, Chan, DS et al. (2012) Dairy products and colorectal cancer risk: a systematic review and meta-analysis of cohort studies. Ann Oncol 23, 3745.Google Scholar
13. Dong, JY, Zhang, L, He, K et al. (2011) Dairy consumption and risk of breast cancer: a meta-analysis of prospective cohort studies. Breast Cancer Res Treat 127, 2331.Google Scholar
14. Abargouei, AS, Janghorbani, M, Salehi-Marzijarani, M et al. (2012) Effect of dairy consumption on weight and body composition in adults: a systematic review and meta-analysis of randomized controlled clinical trials. Int J Obes (Lond) 36, 14851493.Google Scholar
15. Ralston, RA, Lee, JH, Truby, H et al. (2012) A systematic review and meta-analysis of elevated blood pressure and consumption of dairy foods. J Hum Hypertens 26, 313.Google Scholar
16. Aune, D, Norat, T, Romundstad, P et al. (2013) Dairy products and the risk of type 2 diabetes: a systematic review and dose-response meta-analysis of cohort studies. Am J Clin Nutr 98, 10661083.Google Scholar
17. Institute KRE (2004) 2003 Food Balance Sheet: Korea Rural Economic Institute.Google Scholar
18. Institute KRE (2014) 2013 Food Balance Sheet: Korea Rural Economic Institute.Google Scholar
19. Institute KHID (2007) In-Depth Analysis on the 3rd (2005) Korea Health and Nutrition Examination Survey – Nutrition Survey –: Korea Centers for Disease Control and Prevention.Google Scholar
20. Jung, KW, Won, YJ, Kong, HJ et al. (2015) Cancer statistics in Korea: incidence, mortality, survival, and prevalence in 2012. Cancer Res Treat 47, 127141.CrossRefGoogle ScholarPubMed
21. Lim, S, Shin, H, Song, JH et al. (2011) Increasing prevalence of metabolic syndrome in Korea: the Korean National Health and Nutrition Examination Survey for 1998–2007. Diab Care 34, 13231328.Google Scholar
22. American Institute for Cancer Research, World Cancer Research Fund (2007) Food, Nutrition, Physical Activity and the Prevention of Cancer : a Global Perspective: a Project of World Cancer Research Fund International. Washington, DC: American Institute for Cancer Research.Google Scholar
23. Shi, Y, Yu, PW & Zeng, DZ (2015) Dose-response meta-analysis of poultry intake and colorectal cancer incidence and mortality. Eur J Nutr 54, 243250.Google Scholar
24. Guo, Y, Shan, Z, Ren, H et al. (2015) Dairy consumption and gastric cancer risk: a meta-analysis of epidemiological studies. Nutr Cancer 67, 555568.Google Scholar
25. Chen, M, Pan, A, Malik, VS et al. (2012) Effects of dairy intake on body weight and fat: a meta-analysis of randomized controlled trials. Am J Clin Nutr 96, 735747.Google Scholar
26. Kim, J, Kim, YJ, Ahn, YO et al. (2004) Contribution of specific foods to fat, fatty acids, and cholesterol in the development of a food frequency questionnaire in Koreans. Asia Pac J Clin Nutr 13, 265272.Google Scholar
27. Riccardi, G, Giacco, R & Rivellese, AA (2004) Dietary fat, insulin sensitivity and the metabolic syndrome. Clin Nutr 23, 447456.Google Scholar
28. Sieri, S, Krogh, V, Ferrari, P et al. (2008) Dietary fat and breast cancer risk in the European Prospective Investigation into Cancer and Nutrition. Am J Clin Nutr 88, 13041312.Google Scholar
29. Fonseca-Nunes, A, Jakszyn, P & Agudo, A (2014) Iron and cancer risk–a systematic review and meta-analysis of the epidemiological evidence. Cancer Epidemiol Biomarkers Prev 23, 1231.Google Scholar
30. Knize, MG, Salmon, CP, Pais, P et al. (1999) Food heating and the formation of heterocyclic aromatic amine and polycyclic aromatic hydrocarbon mutagens/carcinogens. Adv Exp Med Biol 459, 179193.Google Scholar
31. Wie, GA, Cho, YA, Kang, HH et al. (2014) Red meat consumption is associated with an increased overall cancer risk: a prospective cohort study in Korea. Br J Nutr 112, 238247.Google Scholar
32. Chun, YJ, Sohn, SK, Song, HK et al. (2015) Associations of colorectal cancer incidence with nutrient and food group intakes in Korean adults: a case-control study. Clin Nutr Res 4, 110123.Google Scholar
33. Kim, HJ, Chang, WK, Kim, MK et al. (2002) Dietary factors and gastric cancer in Korea: a case-control study. Int J Cancer 97, 531535.Google Scholar
34. Isa, F, Xie, LP, Hu, Z et al. (2013) Dietary consumption and diet diversity and risk of developing bladder cancer: results from the South and East China case–control study. Cancer Causes Control 24, 885895.Google Scholar
35. Shen, M, Chapman, RS, He, X et al. (2008) Dietary factors, food contamination and lung cancer risk in Xuanwei, China. Lung Cancer 61, 275282.Google Scholar
36. Wang, Z, Zhang, B, Zhai, F et al. (2014) Fatty and lean red meat consumption in China: differential association with Chinese abdominal obesity. Nutr Metab Cardiovasc Dis 24, 869876.Google Scholar
37. Li, Y, Zhai, F, Yang, X et al. (2007) Determinants of childhood overweight and obesity in China. Br J Nutr 97, 210215.Google Scholar
38. Xu, F, Yin, XM & Tong, SL (2007) Association between excess bodyweight and intake of red meat and vegetables among urban and rural adult Chinese in Nanjing, China. Asia Pac J Public Health 19, 39.Google Scholar
39. Kurotani, K, Nanri, A, Goto, A et al. (2013) Red meat consumption is associated with the risk of type 2 diabetes in men but not in women: a Japan Public Health Center-based Prospective Study. Br J Nutr 110, 19101918.Google Scholar
40. Lee, CJ & Joung, HJ (2012) Milk intake is associated with metabolic syndrome – using data from the Korea National Health and Nutrition Examination Survey 2007–2010. Korean J Commun Nutr 17, 795804.Google Scholar
41. Zhang, CX, Ho, SC, Fu, JH et al. (2011) Dairy products, calcium intake, and breast cancer risk: a case-control study in China. Nutr Cancer 63, 1220.Google Scholar
42. Mizoue, T, Kimura, Y, Toyomura, K et al. (2008) Calcium, dairy foods, vitamin D, and colorectal cancer risk: the Fukuoka Colorectal Cancer Study. Cancer Epidemiol Biomarkers Prev 17, 28002807.Google Scholar
43. Matsumoto, M, Ishikawa, S, Nakamura, Y et al. (2007) Consumption of dairy products and cancer risks. J Epidemiol 17, 3844.Google Scholar
44. Kurahashi, N, Inoue, M, Iwasaki, M et al. (2008) Dairy product, saturated fatty acid, and calcium intake and prostate cancer in a prospective cohort of Japanese men. Cancer Epidemiol Biomarkers Prev 17, 930937.Google Scholar
45. Kwon, HT, Lee, CM, Park, JH et al. (2010) Milk intake and its association with metabolic syndrome in Korean: analysis of the third Korea National Health and Nutrition Examination Survey (KNHANES III). J Korean Med Sci 25, 14731479.Google Scholar
46. Kim, J (2013) Dairy food consumption is inversely associated with the risk of the metabolic syndrome in Korean adults. J Hum Nutr Diet 26, Suppl. 1, 171179.Google Scholar
47. Shin, H, Yoon, YS, Lee, Y et al. (2013) Dairy product intake is inversely associated with metabolic syndrome in Korean adults: Anseong and Ansan cohort of the Korean Genome and Epidemiology Study. J Korean Med Sci 28, 14821488.Google Scholar
48. Akter, S, Kurotani, K, Nanri, A et al. (2013) Dairy consumption is associated with decreased insulin resistance among the Japanese. Nutr Res 33, 286292.Google Scholar
49. Pham, TM, Fujino, Y, Kikuchi, S et al. (2010) Dietary patterns and risk of stomach cancer mortality: the Japan collaborative cohort study. Ann Epidemiol 20, 356363.Google Scholar
50. Kumagai, Y, Chou, WT, Tomata, Y et al. (2014) Dietary patterns and colorectal cancer risk in Japan: the Ohsaki Cohort Study. Cancer Causes Control 25, 727736.Google Scholar
51. Hirose, K, Matsuo, K, Iwata, H et al. (2007) Dietary patterns and the risk of breast cancer in Japanese women. Cancer Sci 98, 14311438.Google Scholar
52. Zhang, CX, Ho, SC, Fu, JH et al. (2011) Dietary patterns and breast cancer risk among Chinese women. Cancer Causes Control 22, 115124.Google Scholar
53. Zhang, W, Xiang, YB, Li, HL et al. (2013) Vegetable-based dietary pattern and liver cancer risk: results from the Shanghai women's and men's health studies. Cancer Sci 104, 13531361.Google Scholar
54. Aekplakorn, W, Satheannoppakao, W, Putwatana, P et al. (2015) Dietary pattern and metabolic syndrome in thai adults. J Nutr Metab 2015, 468759.Google Scholar
55. Baik, I, Lee, M, Jun, NR et al. (2013) A healthy dietary pattern consisting of a variety of food choices is inversely associated with the development of metabolic syndrome. Nutr Res Pract 7, 233241.Google Scholar
56. Hong, S, Song, Y, Lee, KH et al. (2012) A fruit and dairy dietary pattern is associated with a reduced risk of metabolic syndrome. Metabolism 61, 883890.Google Scholar
57. Song, Y & Joung, H (2012) A traditional Korean dietary pattern and metabolic syndrome abnormalities. Nutr Metab Cardiovasc Dis 22, 456462.Google Scholar
58. He, DH, Yang, M, Zhang, RH et al. (2015) Dietary patterns associated metabolic syndrome in Chinese adults. Biomed Environ Sci 28, 370373.Google ScholarPubMed
59. Arisawa, K, Uemura, H, Yamaguchi, M et al. (2014) Associations of dietary patterns with metabolic syndrome and insulin resistance: a cross-sectional study in a Japanese population. J Med Invest 61, 333344.Google Scholar
60. Ko, KP, Park, SK, Yang, JJ et al. (2013) Intake of soy products and other foods and gastric cancer risk: a prospective study. J Epidemiol 34, 337343.Google Scholar
61. Kim, JI, Park, YJ, Kim, KH et al. (2003) hOGG1 Ser326Cys polymorphism modifies the significance of the environmental risk factor for colon cancer. World J Gastroenterol 9, 956960.Google Scholar
62. Masaki, M, Sugimori, H, Nakamura, K et al. (2003) Dietary patterns and stomach cancer among middle-aged male workers in Tokyo. Asian Pac J Cancer Prev 4, 6166.Google Scholar
Figure 0

Fig. 1. (Colour online) Secular trend of food intake among Koreans. Grains (), Meats (), Dairy products (), percentage of animal products (shaded). Data are from National Nutrition Survey (1969–1995), Korea National Health and Nutrition Examination Survey (1998–2013)(5).

Figure 1

Fig. 2. (Colour online) Secular trend of nutrient intake among Koreans. Energy (), Fat (), Carbohydrates (), Calcium (). Data are from National Nutrition Survey (1969–1995), Korea National Health and Nutrition Examination Survey (1998–2013)(5).

Figure 2

Fig. 3. (Colour online) Secular trend of cancer incidence among Koreans. Data are taken from Jung et al.(20)

Figure 3

Fig. 4. (Colour online) Secular trend of metabolic syndrome prevalence among Koreans. Data are taken from Lim et al.(21)

Figure 4

Table 1. Meat consumption and cancer in Korean and other Asian countries

Figure 5

Table 2. Meat consumption and metabolic syndrome in Korean and other Asian countries

Figure 6

Table 3. Milk consumption and cancer in Korean and other Asian countries

Figure 7

Table 4. Milk consumption with metabolic syndrome in Korean and other Asian countries

Figure 8

Table 5. Dietary patterns and cancer in Korean and other Asian countries

Figure 9

Table 6. Dietary patterns and metabolic syndrome (metS) in Korean and other Asian countries