Hostname: page-component-7c8c6479df-fqc5m Total loading time: 0 Render date: 2024-03-27T22:57:52.069Z Has data issue: false hasContentIssue false

Dietary sources of five nutrients in ethnic groups represented in the Multiethnic Cohort

Published online by Cambridge University Press:  05 September 2012

Sangita Sharma*
Affiliation:
Department of Medicine, University of Alberta, 5-10 University Terrace, 8303-112 Street, Edmonton, AB, CanadaT6G 2T4
Lynne R. Wilkens
Affiliation:
Epidemiology Program, Cancer Research Center of Hawaii, University of Hawaii, 1236 Lauhala Street, Honolulu, HI 96813, USA
Lucy Shen
Affiliation:
Epidemiology Program, Cancer Research Center of Hawaii, University of Hawaii, 1236 Lauhala Street, Honolulu, HI 96813, USA
Laurence N. Kolonel
Affiliation:
Epidemiology Program, Cancer Research Center of Hawaii, University of Hawaii, 1236 Lauhala Street, Honolulu, HI 96813, USA
*
*Corresponding author: Dr S. Sharma, fax +1 780 248 1611, email gita.sharma@ualberta.ca
Rights & Permissions [Opens in a new window]

Abstract

Data are limited on how dietary sources of energy and nutrient intakes differ among ethnic groups in the USA. The objective of the present study was to characterise dietary sources of energy, total fat, saturated fat, protein, dietary fibre and added sugar for five ethnic groups. A validated quantitative FFQ was used to collect dietary data from 186 916 men and women aged 45–75 years who were living in Hawaii and Los Angeles between 1993 and 1996. Participants represented five ethnic groups: African-American; Japanese-American; Native Hawaiian; Latino; Caucasian. The top ten dietary sources of energy contributed 36·2–49·6 % to total energy consumption, with rice and bread contributing the most (11·4–27·8 %) across all ethnic–sex groups. Major dietary sources of total fat were chicken/turkey dishes and butter among most groups. Ice cream, ice milk or frozen yogurt contributed 4·6–6·2 % to saturated fat intake across all ethnic–sex groups, except Latino-Mexico women. Chicken/turkey and bread were among the top dietary sources of protein (13·9–19·4 %). The top two sources of dietary fibre were bread and cereals (18·1–22 %) among all groups, except Latino-Mexico men. Regular sodas contributed the most to added sugar consumption. The present study provides, for the first time, data on the major dietary sources of energy, fat, saturated fat, protein, fibre and added sugar for these five ethnic groups in the USA. Such data are valuable for identifying target foods for nutritional intervention programmes and directing public health strategies aimed at reducing dietary risk factors for chronic disease.

Type
Full Papers
Copyright
Copyright © The Authors 2012

Cancer, CVD and diabetes ranked among the top ten causes of deaths in the USA in 2010(1). Although chronic disease mortality has declined in recent years(2), widespread prevalence of these diseases remains a critical public health concern. While genetic susceptibility plays an important role in the development of chronic disease, modifiable factors, such as diet, are key determinants(Reference Mokdad, Marks and Stroup3). Mokdad et al. (Reference Mokdad, Marks and Stroup3) attributed an estimated 400 000 deaths in the USA in 2000 to poor diet and physical inactivity and projected more than 500 000 deaths when the effects of overweight on mortality among the 1999–2000 estimates were realised. Substantial evidence supports that poor diet is a preventable risk factor for the development of numerous chronic diseases, and improving diet could result in a decrease in the incidence of and mortality from CVD, cancer and other diet-related chronic conditions(Reference Mokdad, Marks and Stroup3Reference Galimanis, Mono and Arnold7).

The US Department of Agriculture (USDA), the American Heart Association, the National Cancer Institute and the American Diabetes Association advise the US population that meeting recommended nutrient intakes within energy requirements will help reduce the risk for a number of chronic diseases(Reference Eyre, Kahn and Robertson8Reference Bantle, Wylie-Rosett and Albright12). Jointly developed by the US Department of Health and Human Services and the USDA, the Dietary Guidelines for Americans 2010 suggest following a healthful diet by consuming foods to meet nutrient needs in accordance with the Institute of Medicine recommendations(9). Furthermore, the dietary guidelines recommend to keep the total fat intake between 20 and 35 % of energy, consuming less than 10 % of energy from saturated fat, selecting lean meat and poultry, and choosing carbohydrates, such as fibre-rich fruits, vegetables and whole grains as part of a healthful diet(9).

To date, data are limited on dietary sources of energy, total fat, saturated fat, protein, dietary fibre and added sugar among minority ethnic/racial groups in the USA, including African-American, Native Hawaiian, Japanese-American and Latino. Such data are necessary to illustrate how dietary consumption patterns vary between ethnic/racial groups and how these differences may be associated with chronic disease outcomes. Disproportionate rates of diet-related chronic diseases, such as obesity, are observed among minority ethnic/racial groups compared with Caucasian populations(Reference Flegal, Carroll and Ogden13), yet few large-scale studies have been attempted to identify dietary sources of energy and nutrients among different ethnic/racial groups, particularly minorities, in the USA.

The aim of the present study was to characterise the major dietary sources of energy, total fat, saturated fat, dietary fibre and added sugar among the main ethnic/racial groups in the Multiethnic Cohort (MEC). The present results intend to highlight similarities and differences in the types of foods that are consumed as well as the percentage contribution of dietary sources to total energy and selected nutrients by comparing intakes across all ethnic–sex groups represented in the study population.

Methods

The MEC was established in Hawaii and Los Angeles County, California to investigate the associations between diet and cancer among five ethnic/racial groups in the USA: African-Americans (AfAm); Native Hawaiians (NH); Japanese-Americans (JpAm); Latinos (born in Mexico and Central/South America – Latino-Mexico; born in the USA – Latino-US); Caucasians. Study design, recruitment procedures and baseline characteristics have been reported elsewhere(Reference Kolonel, Henderson and Hankin14). In brief, more than 215 000 men and women aged 45–75 years representing the five ethnic/racial groups were enrolled into the MEC study between 1993 and 1996. Ethnicity was self-defined.

Data were collected using a mailed self-administered questionnaire that was specifically developed for the MEC study(Reference Kolonel, Henderson and Hankin14). The twenty-six-page questionnaire included a seventeen-page quantitative FFQ (QFFQ) that collected data on the consumption of more than 180 food items over the past year. The QFFQ was developed from 3 d measured dietary records from sixty men and sixty women of each of the five ethnic/racial groups(Reference Kolonel, Henderson and Hankin14, Reference Stram, Hankin and Wilkens15). Foods that contributed to more than 85 % of the intake of fat, dietary fibre, vitamin A, carotenoids and vitamin C were listed on the QFFQ. Ethnic-specific foods were also included irrespective of their contribution to the diet. The QFFQ measured the amount of food consumed based on a choice of three portion sizes (represented in photographs) specific to each food item listed on the QFFQ and the usual intake frequency based on the categories ranging from ‘never or hardly ever’ to ‘2 or more times a day’. A sub-study was conducted to validate and calibrate the QFFQ using three repeated 24 h dietary recalls collected in each ethnic–sex group(Reference Stram, Hankin and Wilkens15). Average correlations for nutrient densities ranged from 0·57 to 0·74 across ethnic–sex strata, and those for specific nutrient groups were from 0·32 to 0·67 for proteins, 0·46 to 0·77 for total fat, 0·56 to 0·7 for saturated fats and 0·68 to 0·78 for fibre.

Energy and nutrient intakes were calculated based on all QFFQ items(Reference Sharma, Murphy and Wilkens16); similar foods were combined to determine the percentage contribution of each source to the total daily intake of energy, total fat, saturated fat, protein, dietary fibre and added sugar. Participants excluded in the analysis were those with extreme mean energy intake (beyond 3 sd) and/or macronutrient intake (beyond 3·5 sd). As the focus of the present study was to examine nutrient sources among persons of different ethnicities, those who identified themselves being from a mixed ethnic background were also excluded. Latinos born in the Caribbean were also excluded due to the very small number of participants. A total of 186 916 participants were included in the present analysis.

The present study was conducted according to the guidelines laid down in the Declaration of Helsinki, and the protocol was approved by the Institutional Review Boards of the University of Hawaii and the University of Southern California.

Results

Table 1 displays the demographic information of the participants enrolled in the MEC. NH men and AfAm women had the highest average BMI among all ethnic–sex groups, while NH men and NH women reported the highest mean daily energy intakes.

Table 1 Demographic information, BMI and daily energy intake of the participants* (Mean values and standard deviations)

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

The top ten dietary sources of energy contributed from 36·2 % (Latino-Mexico women) to 49·6 % (JpAm men) to total energy intake (Table 2). Across all ethnic–sex groups, the dietary sources of energy intake were similar with rice and bread contributing most, ranging from 11·4 % (Latino-Mexico women) to 27·8 % (JpAm men). However, the percentages of contribution of each source varied among the ethnic–sex groups. Chicken/turkey dishes and pasta with tomato sauce or cheese were in the top ten list for all groups. Cereal was among the top contributors to energy for all ethnic–sex groups (2·3–4·7 %), except Latino-Mexico men. Regular soda contributed between 2·2 % (Latino-Mexico men) and 3·8 % (AfAm men) to total energy intake. Interestingly, beer was a major source of energy intake among men of all ethnic/racial groups with the exception of Latino-Mexico; conversely, beer did not appear among the ten major sources of energy for women of any of the ethnic/racial groups.

Table 2 Ten major sources of ‘energy’ and the percentage (%) contribution of each item in each ethnic–sex group*

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

The ten major dietary sources of fat are presented in Table 3 for all ethnic–sex groups. The top ten sources of total fat contributed 35·1 % (Latino-Mexico women) to 43 % (JpAm men) of total fat intake (Table 3). A top-three food source of fat across all ethnic–sex groups, chicken/turkey dishes, contributed from 4·1 % (Caucasian women) to 7·4 % (AfAm men) to total fat intake. Butter was a top-five food source among all groups except Latino-Mexico men, contributing between 3·6 % (Latino-Mexico women) and 6·2 % (NH women). Peanuts/other nuts also appeared among the top five major sources for men and women in four of the ethnic/racial groups (AfAm, NH, JpAm and Latino-US); the percentage contribution to total fat intake ranged from 4 % for Latino-US men to 5·9 % for JpAm men.

Table 3 Ten major sources of ‘total fat’ and the percentage (%) contribution of each item in each ethnic–sex group*

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

The sources of saturated fats are shown in Table 4. Ice cream, ice milk or frozen yogurt was among the top five contributors to total saturated fat intake for all groups, except Latino-Mexico women. Butter, likewise, was a significant food source of saturated fat for all but Latino-Mexico men, contributing from 4·4 % among Latino-Mexico women to 7 and 7·2 % for NH men and women, respectively.

Table 4 Ten major sources of ‘saturated fat’ and the percentage (%) contribution of each item in each ethnic–sex group*

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

Chicken/turkey dishes were a major contributor to total protein intake across all ethnic–sex groups, topping the list for men and women in four of the ethnic/racial groups (AfAm, NH, Latino-Mexico and Latino-US; Table 5). The first dietary source of protein for JpAm men and women was rice, contributing 12·7 and 10·4 % to protein intake, respectively. Fish was also among the top five major sources in four ethnic/racial groups (AfAm, NH, JpAm and Latino-US); the percentage contribution varied from 4·8 % for AfAm men to 7·7 % for JpAm men. Bread contributed from 4·6 % (Latino-Mexico women) to 7·6 % (Latino-Mexico men) to total protein intake and also appeared among the top five sources across all ethnic–sex groups.

Table 5 Ten major sources of ‘protein’ and the percentage (%) contribution of each item in each ethnic–sex group*

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

Bread and cereals were the top two food sources of dietary fibre among all groups, except Latino-Mexico men, for whom beans replaced cereals as the second highest contributor (Table 6). Together, bread and cereals accounted for 18·1 % (NH women) to 22 % (Caucasian men). Other important dietary sources of fibre were orange, grapefruit or pomelo across all ethnic–sex groups and bananas for men and women in all groups, except AfAm. Regular sodas were the top contributor to added sugar intake, ranging from 17·5 % for JpAm women to 35·2 % for Latino-Mexico men to total consumption (Table 7). The percentage contribution of regular sodas alone is greater than that of the other four major food sources combined for all groups except JpAm and Caucasian women. Other fruit juices/drinks were also a major source of added sugar across all ethnic–sex groups.

Table 6 Ten major sources of ‘dietary fibre’ and the percentage (%) contribution of each item in each ethnic–sex group*

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

Table 7 Ten major sources of ‘added sugar’ and the percentage (%) contribution of each item in each ethnic–sex group*

AfAm, African-American; NH, Native Hawaiian; JpAm, Japanese-American.

* Participants in the Multiethnic Cohort Study in Hawaii and Los Angeles.

Discussion

The present study describes similarities and differences between ethnic/racial groups both in the types of foods that are consumed as well as the percentage contribution of these food sources to total energy and specific nutrient intake. In the present study population, we identified rice, bread, chicken/turkey dishes, sodas and pasta/tomato sauce dishes as the five major sources of energy. In contrast, Cotton et al. (Reference Cotton, Subar and Friday17) identified ‘yeast bread’, ‘beef’, ‘cakes/cookies/quick breads/doughnuts’, ‘soft drinks/soda’ and ‘milk’ as the top five contributors to total energy intake among US adults from 1994 to 1996(18). The differences may be attributed to several factors, including the use of different dietary assessment instruments and different sampling methodologies. Cotton et al. analysed 24 h dietary recalls collected as part of the Continuing Surveys of Food Intakes by Individuals (CSFII), whereas the present study utilised a validated QFFQ that was specifically developed to characterise the dietary consumption patterns of our multiethnic study population. Furthermore, the CSFII used personal weighting factors to compensate for demographic differences between the sampled population and the US population in order to obtain a nationally representative sample(18). By contrast, the present study population comprises the diverse ethnic/racial groups of Hawaii and Los Angeles County, and requires no personal weighting factors to achieve the targeted population sample.

Consumption patterns in the USA have evolved as diverse population groups introduce new foods, novel products appear on the market, and diet trends emerge and fade. The US Department of Health and Human Services and the USDA Dietary Guidelines for Americans 2010 are designed to help Americans make better food choices to promote health and to reduce the risk for chronic diseases(9). While the dietary guidelines contain technical information intended for policymakers, educators, dietitians and other health practitioners, the recommendations are ultimately targeted for the general public to embrace a healthier pattern of eating. The present findings, therefore, may serve to assist nutrition professionals in identifying foods for intervention and translating the dietary guidelines for practical application for specific ethnic/racial minority groups.

The percentage of the US population claiming minority racial or ethnic heritage is growing(19, Reference Kandel20). The US population is becoming increasingly diverse with the nation's minority population reaching 102·5 million in 2007, or 34 % of the total(Reference Bernstein21). It has been shown that ethnic/racial groups are adopting US dietary practices, which are typically high in fat and low in fruits and vegetables(Reference Satia-Abouta, Patterson and Neuhouser22). This trend is particularly alarming when observed in combination with other lifestyle changes, such as decreased physical activity, which may also increase the risk for chronic disease(4). In the present study, we found that the Latino-US group identified different dietary sources of energy and other nutrients compared with the foods consumed by the Latino-Mexico group. For example, while peanuts/other nuts were a top contributor to total fat intake for Latino-US, peanuts/other nuts did not appear among the major sources for Latino-Mexico. Instead, taco salad was a top-ten contributor to total fat among Latino-Mexico compared with Latino-US, for whom taco salad was not an important source. Ethnic differences in dietary sources, as described in the present study, demonstrate a need to consider cultural identities and unique customs when formulating and conveying public health messages and developing and implementing nutrition education and intervention programmes aimed at improving food choices among diverse populations.

While numerous ethnic differences in major dietary sources of energy, total fat, saturated fat, protein, dietary fibre and added sugar have been noted between ethnic/racial groups, an appreciable similarity exists in dietary consumption patterns, consistent among all groups represented in the MEC. Some similarities would be expected, given that the MEC participants were recruited primarily from residents living in two specific geographic areas of the USA. Of note, regular sodas were the primary source of added sugar across all ethnic–sex groups. Combined, regular sodas and other fruit juices/drinks contribute up to almost 50 % to total added sugar consumption. These findings present a tremendous opportunity for public health advocates to help reduce the intake of added sugar, specifically the consumption of sugar-sweetened beverages, which has been linked with an increased risk for a number of diet-related chronic diseases(Reference Hu and Malik23).

The strengths of the present study include the large sample size and the population-specific dietary assessment instrument used to collect data. The MEC QFFQ was specifically developed and validated to describe dietary consumption patterns for the five ethnic/racial groups represented in the present study population. The non-Caucasian sample sizes generated for the MEC are substantially larger than those that are available from other national surveys. The CSFII 1994–6 collected dietary intake data from 16 103 adults(18), which included AfAm and Latinos, but the samples were comparatively small. Furthermore, no national survey has sampled populations in Hawaii, a state that comprises a relatively large number of JpAm and NH. In addition, with the exception of a slightly higher education among cohort participants, baseline characteristics were comparable with census data, supporting the generalisability of these results to the larger US population(Reference Kolonel, Henderson and Hankin14).

Some limitations also warrant mention. Unfortunately, there were a relatively large number of exclusions due to missing data, and the proportion of excluded participants did vary somewhat for the different ethnic–sex groups, ranging from 15 % in Caucasian and JpAm women, to only 2·5 % for NH of both sexes. Although these differences do raise concern regarding introduction of selection bias, with the considerable sample sizes that were still maintained in these analyses, considerable dietary variation would have to have occurred in order to have an impact on these results. Recall bias is also a possible limitation; however, the QFFQ utilised in the MEC characterises total consumption relatively well as demonstrated in calibration and validation assessments(Reference Kolonel, Henderson and Hankin14, Reference Stram, Hankin and Wilkens15). Further, previous studies have demonstrated that FFQ are suitable tools for quantitative assessment of food and nutrient intake(Reference Ke, Toshiro and Fengyan24), although some have suggested that the validity may be higher among women(Reference Carithers, Talegawkar and Rowser25), and could vary by food group(Reference Marks, Hughes and van der Pols26). Another limitation is the collection of data over 15 years ago, thus more recent data would be useful to determine whether changes in the dietary patterns of specific ethnic groups over time may have had an impact on the generalisability of these results to the current population. Nevertheless, no other study on the dietary sources exists for a large sample of the five main ethnic/racial groups in the USA.

Conclusions

The present study is the first to provide data on the major dietary sources of energy, total fat, saturated fat, protein, dietary fibre and added sugar across the main ethnic/racial minority groups in the USA. The present findings may be used to direct public health strategies and develop nutritional guidelines targeted for specific ethnic/racial populations. Continuing efforts to promote a healthful diet and improve food choices must bear special consideration of unique dietary needs distinct to each of these diverse population groups. The present dietary data are particularly valuable for identifying target foods for nutritional intervention programmes aimed at improving dietary adequacy and reducing the risk for chronic disease among the ethnic/racial populations represented in the MEC. Furthermore, these data will facilitate the ongoing investigation of diet–disease associations and observed health disparities among ethnic minority groups.

Acknowledgements

This study could not have been undertaken without the financial support of the following organisations to whom we are very grateful: the National Cancer Institute (grant no. R37 CA54821), the USDA (USDA-NRI New Investigator Award, grant no. 2002-00793) and the American Heart Association of Hawaii (Beginning Grant-in-Aid, grant no. 0265287Z). We also thank Thomas Brown for assistance with the data analysis, as well as Ms Eva Erber, Dr Tony Sheehy, Ms Alison Barr, Dr Mohammadreza Pakseresht and Dr Sara Schaefer for reviewing and editing the manuscript. S. S. and L. N. K. conceptualised the study. L. R. W. and L. S. were responsible for the data management and statistical analyses. S. S. drafted the original manuscript. All authors provided critical review and final approval of the manuscript. None of the authors has any conflicts of interest to report.

References

1 Murphy SL, Xu J & Kochanek KD (2012) NVSR, vol. 60. http://www.cdc.gov/nchs/data/nvsr/nvsr60/nvsr60_04.pdf (accessed 16 April 2012).Google Scholar
2Centers for Disease Control and Prevention (2002) Health, United States, 2002. Rockville, MD: Department of Health and Human Services.Google Scholar
3Mokdad, AH, Marks, JS, Stroup, DF, et al. (2004) Actual causes of death in the United States, 2000. JAMA 291, 12381245.Google Scholar
4Centers for Disease Control and Prevention (2010) Chronic diseases and health promotion. Centers for Disease Control and Prevention Web site. http://www.cdc.gov/chronicdisease/overview/index.htm (accessed accessed 30 April 2012).Google Scholar
5Demark-Wahnefried, W, Rock, CL, Patrick, K, et al. (2008) Lifestyle interventions to reduce cancer risk and improve outcomes. Am Fam Physician 77, 15731578.Google Scholar
6Scarborough, P, Bhatnagar, P, Wickramasinghe, KK, et al. (2011) The economic burden of ill health due to diet, physical inactivity, smoking, alcohol and obesity in the UK: an update to 2006–07 NHS costs. J Public Health (Oxf) 33, 527535.Google Scholar
7Galimanis, A, Mono, ML, Arnold, M, et al. (2009) Lifestyle and stroke risk: a review. Curr Opin Neurol 22, 6068.Google Scholar
8Eyre, H, Kahn, R & Robertson, RM (2004) Preventing cancer, cardiovascular disease, and diabetes: a common agenda for the American Cancer Society, the American Diabetes Association, and the American Heart Association. CA Cancer J Clin 54, 190207.Google Scholar
9US Department of Health and Human Services & US Department of Agriculture (2010) Dietary Guidelines for Americans, 2010, 7th ed.Washington, DC: US Government Printing Office.Google Scholar
10American Heart Association Nutrition Committee, Lichtenstein, AH, Appel, LJ, et al. (2006) Diet and lifestyle recommendations revision 2006: a scientific statement from the American Heart Association Nutrition Committee. Circulation 114, 8296.CrossRefGoogle ScholarPubMed
11Kushi, LH, Doyle, C, McCullough, M, et al. (2012) American cancer society guidelines on nutrition and physical activity for cancer prevention. CA Cancer J Clin 62, 3067.Google Scholar
12Bantle, JP, Wylie-Rosett, J, Albright, AL, et al. (2008) Nutrition recommendations and interventions for diabetes: a position statement of the American Diabetes Association. Diabetes Care 31, Suppl. 1, S61S78.Google Scholar
13Flegal, KM, Carroll, MD, Ogden, CL, et al. (2010) Prevalence and trends in obesity among US adults, 1999–2008. JAMA 303, 235241.CrossRefGoogle ScholarPubMed
14Kolonel, LN, Henderson, BE, Hankin, JH, et al. (2000) A multiethnic cohort in Hawaii and Los Angeles: baseline characteristics. Am J Epidemiol 151, 346357.Google Scholar
15Stram, DO, Hankin, JH, Wilkens, LR, et al. (2000) Calibration of the dietary questionnaire for a multiethnic cohort in Hawaii and Los Angeles. Am J Epidemiol 151, 358370.CrossRefGoogle ScholarPubMed
16Sharma, S, Murphy, SP, Wilkens, LR, et al. (2003) Extending a multiethnic food composition table to include standardized food group servings. J Food Comp Anal 16, 485495.Google Scholar
17Cotton, PA, Subar, AF, Friday, JE, et al. (2004) Dietary sources of nutrients among US adults, 1994 to 1996. J Am Diet Assoc 104, 921930.Google Scholar
18US Department of Agriculture (2004) 1994–96 Continuing Survey of Food Intakes by Individuals [CD-ROM]. Riverdale, MD: Agricultural Research Service.Google Scholar
19Census Bureau (US) (2009) United States population projections: 2000 to 2050. http://www.census.gov/population/www/projections/analytical-document09.pdf (accessed accessed 30 April 2012).Google Scholar
20Kandel, WA (2011) The US foreign-born population: trends and selected characteristics, CRS Report for Congress, Congressional Research Service.Google Scholar
21Bernstein, R (2008) US Hispanic population surpasses 45 million US Census Bureau: Public Information Office.http://www.census.gov/newsroom/releases/archives/population/cb08-67.html (accessed accessed 30 April 2012).Google Scholar
22Satia-Abouta, J, Patterson, RE, Neuhouser, ML, et al. (2002) Dietary acculturation: applications to nutrition research and dietetics. J Am Diet Assoc 102, 11051118.Google Scholar
23Hu, FB & Malik, VS (2010) Sugar-sweetened beverages and risk of obesity and type 2 diabetes: epidemiological evidence. Physiol Behav 101, 4754.Google Scholar
24Ke, L, Toshiro, T, Fengyan, S, et al. (2005) Relative validity of a semi-quantitative food frequency questionnaire versus 3 day weighed diet records in middle-aged inhabitants in Chaoshan area, China. Asian Pacific J Cancer Prev 6, 367381.Google Scholar
25Carithers, TC, Talegawkar, SA, Rowser, ML, et al. (2009) Validity and calibration of food frequency questionnaires used with African-American adults in the Jackson Heart Study. J Am Diet Assoc 109, 11841193.CrossRefGoogle ScholarPubMed
26Marks, GC, Hughes, MC & van der Pols, JC (2006) Relative validity of food intake estimates using a food frequency questionnaire is associated with sex, age, and other personal characteristic. J Nutr 136, 459465.Google Scholar
Figure 0

Table 1 Demographic information, BMI and daily energy intake of the participants* (Mean values and standard deviations)

Figure 1

Table 2 Ten major sources of ‘energy’ and the percentage (%) contribution of each item in each ethnic–sex group*

Figure 2

Table 3 Ten major sources of ‘total fat’ and the percentage (%) contribution of each item in each ethnic–sex group*

Figure 3

Table 4 Ten major sources of ‘saturated fat’ and the percentage (%) contribution of each item in each ethnic–sex group*

Figure 4

Table 5 Ten major sources of ‘protein’ and the percentage (%) contribution of each item in each ethnic–sex group*

Figure 5

Table 6 Ten major sources of ‘dietary fibre’ and the percentage (%) contribution of each item in each ethnic–sex group*

Figure 6

Table 7 Ten major sources of ‘added sugar’ and the percentage (%) contribution of each item in each ethnic–sex group*