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Variety and total number of food items recorded by a true longitudinal group of urban black South African children at five interceptions between 1995 and 2003: the Birth-to-Twenty (Bt20) Study

Published online by Cambridge University Press:  01 June 2008

Titilola M Pedro*
Affiliation:
MRC/WITS Birth-to-Twenty Research Programme, Department of Paediatrics, University of the Witwatersrand Medical School, 7 York Road, Parktown, 2193, Johannesburg, South Africa
Jenny M MacKeown
Affiliation:
MRC Health and Development Research Group, Houghton, Johannesburg, South Africa
Shane A Norris
Affiliation:
MRC Mineral Metabolism Research Unit, Birth-to-Twenty Research Programme, Department of Paediatrics, University of the Witwatersrand Medical School, Parktown, Johannesburg, South Africa
*
Corresponding author: Email [email protected]
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Abstract

Objective

To report on the variety and total number of food items recorded by a true longitudinal group of urban black South African children (n = 143) from the Birth-to-Twenty Study at five interceptions at the ages of 5 (1995), 7 (1997), 9 (1999), 10 (2000) and 13 (2003) years, respectively.

Methods

Dietary intake was assessed using a semi-quantitative food-frequency questionnaire. Frequencies were calculated per week, for each interception and for all five interceptions combined, using SAS.

Results

Five hundred and forty-six different individual food items were recorded 23 480 times for all five interceptions combined. The highest of 124 items was recorded in 1999 contributing 23% of the 546 items recorded. Each of the top 10 items (rice, stiff maize-meal porridge, chicken, sugar, sweets, tea, eggs, full-cream milk, carbonated beverages and oil) contributed between 2.5% and 3% and these items were recorded almost 600 times or more for all interceptions combined (n = 23 840). Rice and stiff maize-meal porridge were the top items recorded 684 and 676 times, both contributing 2.87% and 2.84%, respectively. The variety of food items and the ratio of the food groups to the total number of foods recorded in the present study were not significantly different but the denominators decreased over the five interceptions.

Conclusion

The variety of food items recorded did not vary between 1995 and 2003 – the fact that new items were not added to the questionnaire as the children grew older could have contributed to this phenomenon. However, there was a difference in the ranking of these items that may suggest a change in eating patterns.

Type
Research Paper
Copyright
Copyright © The Authors 2007

According to published literature, urbanisation and nutrition transition has long been recognised as a worldwide phenomenon contributing to emerging crises in both developed and developing countriesReference Popkin1Reference Drewnowski and Popkin5. Even in South Africa, changes in dietary patterns linked to the process of urbanisation and the shift from a traditional lifestyle to a partially Westernised lifestyle and diet have been studied by several authorsReference Jooste, Gouws, Benade and Rossou6Reference MacIntyre, Kruger, Vente and Vorster10, but none have been longitudinal studies.

A fundamental approach to nutrition research is to identify individual food items consumed. These food items supply the nutrients essential for growth and health. As children grow older, they experience new food choices and exert independence on these food itemsReference Lytle, Seifert, Greenstein and McGovern11. It is these individual food items that will have to change to improve the nutrient intake and the ultimate health of the population.

If dietary habits and nutrition behaviour are dynamic and constantly changingReference Alexy, Sichert-Hellert, MacIntyre, Gerike, Swart and Kersting12Reference Richardson, Sinwel, Cleaton-Jones, Granath, MacKeown, Walker, Cleaton-Jones, Granath and Richardson15, longitudinal studies are essential to determine the change among the same individual over time. Although the nutrient intake of South African populations has been exploredReference Jooste, Gouws, Benade and Rossou6, Reference Bourne, Langenhoven, Steyn, Jooste, Laubscher and Van der Vvyver7, Reference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14Reference MacKeown, Pedro and Norris20, only the energy, macro- and micronutrient intakes of a true longitudinal group of urban black South African children have been examined in the Birth-to-Twenty (Bt20) Study at fourReference MacKeown, Cleaton-Jones and Norris19 and at two interceptionsReference MacKeown, Pedro and Norris20. There has not been a longitudinal study on the actual food items consumed by the same children over a period of time.

Scientific evidence on the intake of individual food items at a particular point in time is availableReference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8, Reference MacKeown, Cleaton-Jones, Granath, Richardson and Sinwel21Reference MacKeown and Faber24, Reference Pedro29. The need for new, recent information is crucial to determine the ongoing change in the dietary patterns of South African children.

The Bt20 Study, a continuation of the Birth-To-Ten (BTT) Study, started in 1990 and is planned to continue to 2010. It is the first and only longitudinal study on food and nutrient intake of South African children and the largest running study on child development in Africa.

Objective

This paper reports on the variety and total number of food items recorded by a true longitudinal group of urban black South African children (n = 143) from the Bt20 Study at five interceptions at the ages of 5 (1995), 7 (1997), 9 (1999), 10 (2000) and 13 (2003) years, respectively.

Methods

Detailed information about the Bt20 Study has been published elsewhereReference Yach, Cameron, Padayachee, Wagstaff, Richter and Fonn25Reference Pedro29. Prior to this study, informed written consent was obtained from the participant’s parents/guardians in accordance with the Ethical Committee of the University of Witwatersrand Committee (medical) for Research on Human Subjects.

Population sample

The Bt20 Study is a longitudinal observation study initiated to determine the biological, environmental, social, economic and psychosocial factors associated with the survival and health of urban South African childrenReference Yach, Cameron, Padayachee, Wagstaff, Richter and Fonn25Reference Pedro29, living in South Africa’s largest metropolitan area, the Johannesburg/Soweto area. The original sample size for the BTT Study was based on a representative proportion of the total South African population according to the 1994 population census30. The black community now represents 79% of the total South African population according to the 2001 census31. Hence, the true longitudinal core sample for this study comprised 143 urban black children from the Bt20 Study who had nutrition information for all five interceptionsReference Pedro29 and there is no indication whether these 143 subjects were similar to those lost to follow-up. Figure 1 shows the number of children with nutrition information at each separate interception of the Bt20 Study.

Fig. 1 True longitudinal group of urban black children with nutrition information at all five interceptions (1995, 1997, 1999, 2000 and 2003)

Dietary assessment

The same semi-quantitative food-frequency questionnaire (FFQ) was used at each nutrition interception of the Bt20 Study because of the large number of subjects living in a culturally diverse populationReference Steyn, Nel and Casey23, Reference MacIntyre, Venter and Vorster32, Reference MacIntyre, Venter and Vorster33. The FFQ method was validated by Margetts et al.Reference Margetts, Cade and Osmond34, and has been found to be reproducible, relatively valid and culturally sensitive in assessing the dietary intake of black South African adults and children older than 15 years in the North West ProvinceReference MacIntyre, Venter and Vorster32, Reference MacIntyre, Venter and Vorster33. Parents/guardians or the older children themselves were asked by trained multilingual interviewers to indicate how frequently listed food items were consumed over a weekly period.

Data management

The same interviewers coded the dietary data on to computer coding sheets using the South African Medical Research Council (MRC) Food Composition Tables and CodesReference Langenhoven, Kruger, Gouws and Faber35. Either recorded or standard portion sizes were used based on the use of the National Research Institute for Nutritional Diseases (NRIND) Food Quantities ManualReference Langenhoven, Conradie, Gouws, Wolmarans and van Eck36. The SAS version 6.137 software package was used for statistical analysis.

The raw data were rearranged, merged by child case number and finally the true longitudinal group of 143 children was extracted by the subject’s case number. The frequencies were calculated for the number of times each food item was recorded per week, for all five interceptions combined and for each interception separately. The total number of times each food item was recorded for all five interceptions combined was divided by the total number of times all food items at all five interceptions combined were recorded (23 840) and expressed as a percentage. The food items were ranked in descending order according to their percentage contribution to the total number of recordings for all five interceptions and then within the six food groups (grain/cereal/breakfast cereal/porridges and other starches; meat and meat substitutes; fruits and vegetables; fats and oils; milk and milk products; and miscellaneous) listed in the semi-quantitative FFQ according to the mean number of recordings over the five interceptions. In addition, the total number of food items for all the six food groups for each of the five interceptions was calculated (Y). The ratio was then calculated for the number of food items recorded in each of the six food groups at each interception (X) by dividing X/Y.

Results

A total of 546 different individual food items were recorded 23 840 times over the five interceptions. The highest number of food items recorded was 124 (1999) and 123 (2003), being 22.7% and 22.5%, followed by 113 food items (21%) in 2000, 95 (17.4%) in 1995 and 91 (16.6%) in 1997, respectively. Forty-one items contributed 1% or more of the total number of recordings for all five interceptions combined and this was used as a cut-off point as the remaining food items were recorded too infrequently.

Table 1 shows the top 41 food items ranked in descending order according to the total number of times each food item was recorded and their percentage contributions for all five interceptions combined (n = 23 840). The top 10 food items each contributed between 2.5% and 3% to the overall total number of recordings while the next 23 food items each contributed 1.5–2.3% and lastly eight food items each contributed 1–1.5%. Rice and stiff maize-meal porridge were the top food items, recorded 684 and 676 times, respectively, contributing <3% of the total recordings. The third food item recorded 672 times was chicken, contributing 2.82% of the total number of recordings for all food items for all interceptions. Interestingly, four food items, namely sugar (657 times), sweets (649 times), tea (646 times) and carbonated beverages (600 times), were from the miscellaneous group. The food items that featured down on the ranked list were mixed vegetables (266 times), non-dairy creamer (241 times) and fruit juice (239 times), contributing 1.110%, 1.01% and 1.00%, respectively.

Table 1 The top 41 food items ranked in descending order according to the total number of times each food item was recorded and their percenatge contribution for all five interceptions combined (n = 23 840)

Table 2 shows the top 41 food items ranked in descending order within the food groups according to the mean number of recordings over the five interceptions. The ratio of fruit and vegetables decreased from 0.18 in 1995 to 0.12 in 2003. However, the ratio of other food groups remained fairly stable over the five interceptions.

Table 2 The top 41 food items ranked in descending order within the food-frequency questionnaire food groups according to the mean number of recordings over the five interceptions

SD – standard deviation; a – mean number of recordings over five interceptions; b – decrease (−) or increase (+) in the number of recordings from 1995 to 2003; Ratio – the number of food items recorded in each of the six food groups at each interception (X)/the total number of food items for all the six food groups for each of the five interceptions (Y).

The number of recordings of the five food items from the grain/cereal/breakfast cereal/porridges and other starches group showed an overall decrease and was not stable. The highest decrease being for soft maize-meal porridge (125 in 1995 to 70 in 2003).

Within interceptions (1997–2000) there were fluctuations in the number of recordings of the eight food items from the meat and meat substitutes group (Table 2). Only peanut butter (a cheap source of protein) and fried fish showed a large decrease in the number of recordings over the period of investigation (129 to 71 and 111 to 40 from 1995 to 2003, respectively).

However, the number of recordings of fruits and vegetables (apple, banana, orange, cabbage, mashed potatoes, pumpkin and mixed vegetables) decreased steadily over this period. Only fruit juice showed a highly irregular pattern of recordings with an overall increase of 74 from 1995 to 2003.

Oil was recorded between 133 and 139 times in 1995, 1997 and 1999 but gradually decreased to 118 times in 2000 and to 72 times in 2003. Within this food group, there were fluctuations between interceptions in the number of recordings for salad dressing, butter, margarine and non-dairy creamers. However, recordings for ice-cream and margarine showed an overall increase from 1995 to 2003.

In the group of milk and milk products, full-cream milk was recorded between 127 and 133 times (1995–2000), but then decreased to 99 times in 2003. The number of recordings for custard and low-fat yoghurt showed irregular patterns of consumption over this period.

Eleven food items (sugar, sweets, tea, carbonated beverages, biscuits, crisps, jam, popcorn, chocolate, jelly and coffee) were from the miscellaneous group. Most of these items showed an overall decrease in the number of times recorded from 1995 to 2003, except for coffee, which increased minimally over this time (from 70 to 82 times).

Discussion

Main findings

A total of 546 different individual food items were recorded between 1995 and 2003. The highest number of food items was recorded in 1999 (124) and 2003 (123). These 546 items were recorded 23 840 times over the five interceptions combined. Only 41 items contributed 1% or more of the total number of recordings.

Rice and stiff maize-meal porridge were the top items from the grain and cereal group; there was a decrease in the number of recordings of the grain and cereal group, the fruit and vegetable group and the milk and milk products group over the five interceptions. However, among the meat and meat substitutes, chicken, cheese and polony increased over this time as did margarine and ice-cream among the fats and oils. Among the miscellaneous food group, only sugar and coffee showed a minimal increase in the number of recordings. The number of recordings for the remaining items decreased over 8 years.

Methodology

No method has been able to yield precise and accurate quantitative amounts of foods eaten in obtaining the usual food intake of free-living individualsReference Kigutha38, Reference Borrelli39. The FFQ may be the optimal method for epidemiology studies when looking at the eating patterns of large, culturally diverse populations, such as the Bt20, for its ease of application and cost effectivenessReference Steyn, Nel and Casey23, Reference Pedro29, Reference MacIntyre, Venter and Vorster32, Reference MacIntyre, Venter and Vorster33. Although this semi-quantitative FFQ was designed to measure the foods and usual intake of these children at baseline, it did not include new foods as they grew older. Hence, omissions of foods from the food list may result in underestimationReference Pedro29 and this may be a weakness of the study, especially as the study attempts to measure food intake over time. Not only did the children get older as the study progressed, but the foods available on the market also probably changed. Allowing for new foods to be added to the questionnaire would have given a different result and this has been planned for a future publication. However, using the same questionnaire at all interceptions did allow for consistency.

Comparisons with other South African studies

Many longitudinal research studies have shown that food habits change over timeReference Alexy, Sichert-Hellert, MacIntyre, Gerike, Swart and Kersting12, Reference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14, Reference Inchley, Todd, Bryce and Currie40 but there is paucity of data on the longitudinal assessment of food item intakes in South Africa to show this. Other studies on individual food items consumed by very young rural black childrenReference MacKeown and Faber41, young rural and urban childrenReference MacKeown and Faber24, preschoolersReference MacKeown, Cleaton-Jones, Granath, Richardson and Sinwel21, Reference MacKeown, Cleaton-Jones and Senekal42, schoolchildrenReference Faber, Smuts and Benade22, Reference Steyn, Wicht, Rossouw, Kotze and Van Eck43 and adultsReference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8 are available, but true comparison with these other studies cannot be made.

The only longitudinal studyReference MacKeown, Cleaton-Jones and Norris19 conducted on these same Bt20 urban black South African children on their energy, macro- and micronutrient intake at four interceptions was between 1995 and 2000Reference MacKeown, Cleaton-Jones and Norris19. This studyReference MacKeown, Cleaton-Jones and Norris19 concluded that the nutrient intake of these children deteriorated between 1995 and 2000. These urban black children had the best nutrient intake at 5 years of age in 1995, when the lowest percentage fell below the Recommended Dietary Allowance (RDA) for most nutrients, while the worst nutrient intake was at 10 years when the highest percentage of the children fell below the RDAReference MacKeown, Cleaton-Jones and Norris19. However, no individual food items were included in this study.

The results of the present study are similar to those of previous authorsReference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8, Reference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14, Reference MacKeown, Pedro and Norris20, Reference Steyn, Nel and Casey23 in that both stiff and soft maize-meal porridge are important staples among the black community. The National Food Consumption Survey on children aged 1–9 yearsReference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14 and Bourne et al.’sReference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8 study among the urban black community also reported rice among the most commonly consumed food items. Rice also ranked the top item in the present study (Table 2).

Among meat and meat substitutes, chicken and eggs ranked high in the present study. Similar findingsReference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14, Reference Steyn, Nel and Casey23, Reference Scholtz, Vorster, Matshego and Vorster44 also reported frequent consumption of chicken among the study group.

This study observed a decrease in the number of recordings of fruit and vegetables over the five interceptions. Although people eat more than one type of fruit and vegetablesReference Love and Sayed45Reference de Villiers and Senekal47, consumption of fruits such as apples, banana and oranges decreased in this study but this could have been replaced by other fruits, which were not picked up because of the cut-off point usedReference Pedro, MacKeown and Norris46. Low intakes of fruits and vegetables were also reported in other studies on different South African communitiesReference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8, Reference MacIntyre, Kruger, Vente and Vorster10, Reference Love and Sayed45Reference MacKeown, Cleaton-Jones and Edwards48.

Oil ranked high within the fats and oils food group (Table 2). The use of oil was also reported in the National Food Consumption Survey studyReference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14. The number of recordings of ice-cream increased from 1995 to 2003 among these children. The consumption of ice-cream was also noted in a study on the frequency of food items consumed by very young rural and urban African childrenReference MacKeown and Faber24.

Evidence that the consumption of milk decreases as schoolchildren enter adolescenceReference Lytle, Seifert, Greenstein and McGovern11 was observed in the number of recordings of milk and milk products over the five interceptions. Other researchersReference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8, Reference MacKeown, Pedro and Norris20, Reference Pedro29, Reference Scholtz, Vorster, Matshego and Vorster44, Reference de Villiers and Senekal47 have also reported low and inadequate intake of milk products and this confirms the low intake of milk in the present study with the lowest number of recordings (99) in 2003 (Table 2). As Bourne et al. Reference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8 stated ‘sour milk presents less storage problems than fresh milk and is part of the traditional diet among the black community’Reference Bourne, Langenhoven, Steyn, Nesamvuni and Laubscher8 and most importantly affordability because dairy products are relatively expensive in South AfricaReference Scholtz, Vorster, Matshego and Vorster44.

Studies have shown frequent intake of sugar, tea and coffee among the miscellaneous food group, with tea and coffee consistently being reported as the usual beverages among both the rural and urban black communitiesReference Faber, Smuts and Benade22, Reference MacKeown and Faber24, Reference MacKeown, Cleaton-Jones and Edwards48.

With regard to sugar, a frequent consumption was found among 5-year-old urban black children living in the Johannesburg/Soweto area of the Gauteng Province of South Africa, with the intake remaining relatively constant between 1991 and 1995Reference Pedro, MacKeown and Norris46. In addition, many younger children in Faber et al.’sReference Faber, Smuts and Benade22 study reported drinking tea with sugar regularly and MacIntyre et al.’s study on dietary intakes in different stages of transition in the North West Province of South Africa (THUSA study) also noted sugar consumption by almost all of the participantsReference Drewnowski and Popkin5. Although sugar was not quantified by other authorsReference Drewnowski and Popkin5, Reference Labadarios, Steyn, Maunder, MacIntyre, Gerike and Swart14, Reference Faber, Smuts and Benade22, Reference MacKeown and Faber24, Reference Pedro29, Reference Pedro, MacKeown and Norris46Reference MacKeown, Cleaton-Jones and Edwards48, it was popular and similar to the present study. The number of recordings of sugar was high and remained relatively stable over the 8 years (Table 2). Authors have also observed frequent intake of food items such as sweets and chocolateReference Faber, Smuts and Benade22, and carbonated beveragesReference MacKeown and Faber24, among children in South Africa. Similarly, these items were among the top 41 recorded in this study.

The variety of food items and the ratio of the food groups to the total number of foods recorded in the present study were not significantly different but the denominators decreased over the five interceptions. However, there was a difference in the number of recordings during this period of 8 years. This probably indicates a change in eating patterns among this group of urban black South African children and the fact that new items were not added to the questionnaire as the children grew older could have contributed to this phenomenon.

The low and infrequent recordings of fruits and vegetables are of great concern. These foods were replaced with processed meats; cheese, fats and fruit juice. In addition, the steady and relatively high recordings of miscellaneous foods reflects a shift towards a Western diet (sugar-based products). The study has provided valuable information that identifies the food types and population age groups that are at risk and that should be targeted. It has also provided guidelines for government policies for nutrition intervention strategies that will lead to healthy dietary habits among children and adolescents in a country undergoing nutritional transition.

Acknowledgements

We would like to thank the BTT and Bt20 coordinators, staff and interviewers. We also acknowledge the following sponsors and funders of the Birth-to-Twenty Study: South African Medical Research Council (MRC), Wellcome Trust (UK), Anglo American Chairman’s Fund, University of the Witwatersrand, Human Sciences Research Council of South Africa (HSRC), South Africa Netherlands Research Programme for Alternatives in Development (SANPAD).

References

1Popkin, BM. The nutrition transition in low income-countries. Nutrition Reviews 1993; 52 (9): 285298.CrossRefGoogle Scholar
2Popkin, BM, Keyou, G, Zhai, F, Guo, X, Ma, H, Zohoori, N. The nutrition transition in China: a cross-sectional analysis. European Journal of Clinical Nutrition 1993; 47 (5): 333346.Google Scholar
3Popkin, BM. The nutrition transition in low income-countries: an emerging crisis. Nutrition Reviews 1994; 52 (9): 285298.CrossRefGoogle ScholarPubMed
4Monteiro, CA, Mondini, L, de Souza, AL, Popkin, BM. The nutrition transition in Brazil. European Journal of Clinical Nutrition 1995; 49 (2): 105113.Google ScholarPubMed
5Drewnowski, A, Popkin, BM. The nutrition transition: new trends in the global diet. Nutrition Reviews 1997; 55 (2): 3143.CrossRefGoogle ScholarPubMed
6Jooste, PL, Gouws, E, Benade, AJS, Rossou, JE. Diet and serum lipids of black migrant labourers exposed to a western urban environment. South African Journal of Food Science & Nutrition 1990; 2 (4): 8587.Google Scholar
7Bourne, LT, Langenhoven, ML, Steyn, K, Jooste, PL, Laubscher, JA, Van der Vvyver, E. Nutrient intake in the urban African population of the Cape Peninsula, South Africa: the Brisk Study. Central African Journal of Medicine 1993; 39 (12): 238247.Google ScholarPubMed
8Bourne, LT, Langenhoven, ML, Steyn, K, Nesamvuni, AN, Laubscher, JA. The food and meal pattern in the urban African population of the Cape Peninsule, South Africa: the BRISK Study. Central African Journal of Medicine 1994; 40 (6): 140148.Google Scholar
9Vorster, HH, Bourne, LT, Venter, CS, Oosthuizen, W. Contribution of nutrition to the health transition in developing countries: a framework for research and intervention. Nutrition Reviews 1999; 57 (11): 341349.CrossRefGoogle Scholar
10MacIntyre, UE, Kruger, HS, Vente, CS, Vorster, HH. Dietary intakes of an African population in different stages of transition in the North West Province, South Africa: the THUSA study. Nutrition Reviews 2002; 22: 239256.Google Scholar
11Lytle, L, Seifert, S, Greenstein, J, McGovern, P. How do children’s eating patterns and food choices change over time? Results from a cohort study. American Journal of Health Promotion 2000; 14: 222228.CrossRefGoogle ScholarPubMed
12Alexy, U, Sichert-Hellert, W, MacIntyre, U, Gerike, G, Swart, R, Kersting, M. Fifteen-year trend in energy and macronutrient intake in German children and adolescence: results of the DONALD study. British Journal of Nutrition 2002; 87: 595604.CrossRefGoogle ScholarPubMed
13Murata, M. Secular trends in growth and changes in eating patterns of Japanese children. American Journal of Clinical Nutrition 2000; 72 (Suppl.): 1379S1383S.CrossRefGoogle ScholarPubMed
14Labadarios, D, Steyn, N, Maunder, E, MacIntyre, U, Gerike, G, Swart, R, et al. The National Food Consumption Survey (NFCS): South Africa, 1999. Public Health Nutrition 2005; 8: 533543.CrossRefGoogle ScholarPubMed
15Richardson, BD, Sinwel, RE, Cleaton-Jones, PE, Granath, L, MacKeown, JM, Walker, ARP, et al. Nutrient intake. In: Cleaton-Jones, PE, Granath, L, Richardson, BD, eds. Nutrient Intake, Dietary Habits, Anthropometric Status, Oral Hygiene, and Salivary Factors and Microbiota in South African Black, Indian and White 4–5-year-old Children. Parrow: South African Medical Research Council (MRC), 1991; 5485.Google Scholar
16Langenhoven, ML, Swanepoel, ASP, Steyn, M, Bremmer, B, van Wyk Kotze, TJ. Macronutrient intake of preschool children and the contribution of specific food groups. South African Journal of Food Science and Nutrition 1991; 3: 69.Google Scholar
17MacKeown, JM, Cleaton-Jones, PE, Perdrau, GG. Energy, macronutrient intake of one-year-old South African urban children: The Birth-to-Ten (BTT) Study. Paediatric and Perinatal Epidemiology 1996; 10: 150160.CrossRefGoogle ScholarPubMed
18MacKeown, JM, Cleaton-Jones, PE, Edwards, AW, Turgeon-O’Brien, H. Energy, macro- and micronutrient intake of 5-year-old urban black South African children in 1984 and 1995. Paediatric and Perinatal Epidemiology 1998; 12: 297312.CrossRefGoogle ScholarPubMed
19MacKeown, JM, Cleaton-Jones, PE, Norris, SA. Nutrient intake among a longitudinal group of urban black South African children at four interceptions between 1995 and 2000 (Birth-to-Ten Study). Nutrition Research 2003; 23: 185197.CrossRefGoogle Scholar
20MacKeown, JM, Pedro, TM, Norris, SA. Energy, macro- and micronutrient intake among a true longitudinal group of South African adolescents at two interceptions (2000 and 2003): the Birth-to-Twenty (Bt20) Study. Public Health Nutrition 2007; 10: 635643.CrossRefGoogle ScholarPubMed
21MacKeown, JM, Cleaton-Jones, PE, Granath, L, Richardson, BD, Sinwel, RE. A study of the relative amounts of food items consumed by South African preschool children. South African Journal of Food Science and Nutrition 1989; 1: 1923.Google Scholar
22Faber, M, Smuts, CM, Benade, AJS. Dietary intake of primary school children in relation to food production in a rural area in KwaZulu-Natal, South Africa. International Journal of Food Science and Nutrition 1999; 50: 5764.CrossRefGoogle Scholar
23Steyn, NP, Nel, JH, Casey, A. Secondary data analyses of dietary surveys undertaken in South Africa to determine usual food consumption of the population. Public Health Nutrition 2003; 6: 631644.CrossRefGoogle ScholarPubMed
24MacKeown, JM, Faber, WM. Frequency of food items consumed by young rural and urban African children – essential knowledge to provide dietary advice in caries prevention. International Dental Journal 2004; 54: 284290.CrossRefGoogle Scholar
25Yach, D, Cameron, N, Padayachee, N, Wagstaff, LA, Richter, L, Fonn, S. Birth-to-Ten – child health in South Africa in the 1990’s. Rationale and methods of a birth cohort study. Paediatric and Perinatal Epidemiology 1991; 5: 211233.CrossRefGoogle Scholar
26Fonn, S, De Beer, M, Kgamphe, S, McIntyre, J, Cameron, N, Padayachee, GN, et al. Birth-to-Ten – pilot studies to test the feasibility of a cohort study investigating the effects of urbanisation in South Africa. South African Medical Journal 1991; 79: 449454.Google ScholarPubMed
27Anderson, A, Richter, LM. Birth to Ten: error detection and correction in a longitudinal address database. South African Journal of Epidemiology and Infection 1994; 9: 1619.Google Scholar
28Richter, LM, Yach, D, Cameron, N, Griesel, RD, de Wet, T, Anderson, A. Enrolment into Birth to Ten (BTT): sample and population characteristics. Paediatric and Perinatal Epidemiology 1995; 9: 109120.CrossRefGoogle Scholar
29Pedro, TM. Comparison of individual food item intakes of a true longitudinal group of South African children at five interceptions between 1995 and 2003; the Birth-to-Twenty (Bt20) Study. MSc Thesis, University of the Witwatersrand, Johannesburg, 2006.Google Scholar
30 Steenkamp HA. Population Estimates for the RSA by Magisterial District and Province, 1994. Research Report No. 212. Pretoria: Bureau of Market Research, University of South Africa, 1994.Google Scholar
31 Statistics South Africa. Census in Brief, 2001. Report No. 03-02-03. Pretoria: Statistics South Africa, 2003.Google Scholar
32MacIntyre, UE, Venter, CS, Vorster, HH. A culture sensitive quantitative food frequency questionnaire used in an African population 1. Development and reproducibility. Public Health Nutrition 2001; 4: 5362.CrossRefGoogle Scholar
33MacIntyre, UE, Venter, CS, Vorster, HH. A culture sensitive quantitative food frequency questionnaire used in an African population 2. Relative validation by 7-day weighed records and biomarkers. Public Health Nutrition 2001; 4: 6371.CrossRefGoogle Scholar
34Margetts, BM, Cade, JE, Osmond, C. Comparison of a food frequency questionnaire with a diet record. International Journal of Epidemiology 1989; 18: 868873.CrossRefGoogle ScholarPubMed
35Langenhoven, ML, Kruger, M, Gouws, E, Faber, M. Research Institute for Nutritional Diseases (RIND) Food Composition Tables, 3rd ed. Parrow: South African Medical Research Council, 1991; 1248.Google Scholar
36Langenhoven, ML, Conradie, PJ, Gouws, E, Wolmarans, P, van Eck, M. National Research Institute of Nutritional Diseases (NRIND) Food Quantities Manual, 2nd ed. Parrow: South African Medical Research Council, 1991; 213.Google Scholar
37 SAS Institute INC. SAS/STAT User’s Guide, Version 6, 4th edn. Vol. 1. Cary, NC: SAS Institute Inc., 1989; 943.Google Scholar
38Kigutha, HN. Assessment of dietary intake in rural communities in Africa: experiences in Kenya. American Journal of Clinical Nutrition 1997; 65 (Suppl.): 1168S1172S.CrossRefGoogle ScholarPubMed
39Borrelli, R. Collection of food intake data: a reappraisal of criteria for judging the methods. British Journal of Nutrition 1990; 63: 411417.CrossRefGoogle Scholar
40Inchley, J, Todd, J, Bryce, C, Currie, C. Dietary trends among Scottish school children in the 1990s. Journal of Human Nutrition and Dietetics 2001; 14: 207216.CrossRefGoogle ScholarPubMed
41MacKeown, JM, Faber, WM. Frequency of consumption of cariogenic food items by 4-month-old to 24-month-old children: comparison between two rural communities in KwaZulu-Natal, South Africa. International Journal of Food Sciences and Nutrition 2005; 55: 95103.CrossRefGoogle Scholar
42MacKeown, JM, Cleaton-Jones, PE, Senekal, M. Individual food items in the diets of preschool children – energy, total protein, carbohydrate, fibre, added sugar and fat intake. South African Journal of Food Science and Nutrition 1991; 6: 9498.Google Scholar
43Steyn, NP, Wicht, CL, Rossouw, JE, Kotze, TJ van W, Van Eck, M. Nutritional status of 11-year-old children in the Western Cape. I Dietary intake. South African Journal of Food Science & Nutrition 1989; April: 1520.Google Scholar
44Scholtz, SC, JrVorster, HH, Matshego, L, Vorster, HH. Foods from animals can be eaten everyday – not a conundrum. South African Journal of Clinical Nutrition 2001; 14 (Suppl. 3): S39S47.Google Scholar
45Love, P, Sayed, N. Eat plenty of vegetables and fruits everyday. South African Journal of Clinical Nutrition 2001; 14 (Suppl. 3): S24S32.Google Scholar
46Pedro, TM, MacKeown, JM, Norris, SA. Percentage of a true longitudinal group of South African children consuming individual food items at 5 interceptions (1995–2003): the Birth-to-Twenty (Bt20) Study. South African Journal of Clinical Nutrition 2006; 19 (Suppl. S1–S28): 19.Google Scholar
47de Villiers, A, Senekal, M. Determinants of growth failure in 12–24 month-old children in a high-density urban slum community in East London, South Africa. European Journal Clinical Nutrition 2002; 56: 12311241.CrossRefGoogle Scholar
48MacKeown, JM, Cleaton-Jones, PE, Edwards, AW. Energy and macronutrient intake in relation to dental caries incidence in urban black South African preschool children in 1991 and 1995: the Birth-to-Ten Study. Public Health Nutrition 2000; 3: 313319.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 True longitudinal group of urban black children with nutrition information at all five interceptions (1995, 1997, 1999, 2000 and 2003)

Figure 1

Table 1 The top 41 food items ranked in descending order according to the total number of times each food item was recorded and their percenatge contribution for all five interceptions combined (n = 23 840)

Figure 2

Table 2 The top 41 food items ranked in descending order within the food-frequency questionnaire food groups according to the mean number of recordings over the five interceptions