Tanzania national panel survey

The TNPS Wave 4 data were accessed via the Living Standards Measurement Study of the World Bank Microdata Library⁽²³⁾. The TNPS is a nationally representative household survey that collects information on the living standards of the Tanzanian population, including their socio-economic characteristics, consumption, agricultural production and non-farm income generating activities. The survey is designed to follow the same households over time to track changes in living conditions. In TNPS Wave 4, a nationally representative subsample of the panel cohort was selected as part of an ‘Extended Panel’ to support longitudinal comparisons with previous survey rounds⁽²³⁾. In addition, to refresh samples with biases from the changes in boundaries, demographics or population information and reduce the risk of selection bias escalation, a new nationally representative sample was selected, called the ‘Refresh Panel’ (n 3360 households), which we used for this analysis. The ‘Refresh Panel’ aimed to create a sample that was broadly representative of the current population, given that participants in the panel sample get older over successive rounds. The TNPS Wave 4 sample design has four analytical strata: Dar es Salaam, other urban areas in Tanzania Mainland, rural areas in Tanzania Mainland and Zanzibar. Within each stratum, clusters were randomly selected as primary sampling units, with the probability of selection proportional to the population size of the stratum. The survey consisted of fifty-one design strata, corresponding to a rural/urban designation for each of the twenty-five regions with Dar es Salaam as a purely urban stratum. In urban areas, clusters are equivalent to census enumeration areas (EA), while in rural areas, clusters are equivalent to villages. Eight households were randomly chosen in each cluster. During the survey, one selected EA in Dar es Salaam was deleted because the houses in the EA had been demolished to pave the way for expansion of a road. The resulting sample consists of 3352 households across 419 EAs/villages. Sixty-two households did not report any food consumption in the previous 7 d, or the household reported that no member consumed foods in the household, and these households were excluded from the subsequent analysis. Therefore, a total of 3290 households (1332 and 1958 households in urban and rural areas, respectively, and 539, 529, 1757 and 465 households from Dar es Salaam, Mainland other urban areas, Mainland rural areas and Zanzibar, respectively) were analysed.

Food consumption data

The enumerators asked a household member (typically an adult woman) to recall foods consumed over the past 7 d by all members of the household, using a predefined list of sixty distinct food items/food groups (e.g. ‘Cooking oils’), with quantities recorded in ‘kilograms’, ‘grams’, ‘litre’, ‘millilitre’ or ‘pieces’. The source of each item consumed was recorded as purchases, own production and gifts/other sources. The module did not include foods consumed outside the home.

For the quantities of food items consumed using its water weight equivalent, the weights were adjusted for liquid food items such as cooking oils⁽²⁴⁾, and the non-edible portions of foods (e.g. banana skins) were subtracted^{(25–Reference Lukmanji, Hertzmark and Mlingi27)}. The quantities reported using the unit ‘pieces’ (e.g. ‘Eggs’, ‘Chicken and other poultry’, ‘Sweets’, ‘Maize (green, cob)’ and ‘Ripe bananas’) were estimated using Food Portion Size Databases in the Tanzania Food Composition Table^{(Reference Lukmanji, Hertzmark and Mlingi27)} and converted to metric units (i.e. grams).

Food composition data

National and regional food composition tables (FCT) were reviewed for use in the current study. The selection of food composition table nutrient values to match with each food item was prioritised based on the number of available foods and relevant nutrients (including moisture content) and geographic and cultural relevance. Thus, the primary source of food matches was the Kenya FCT⁽²⁵⁾, followed by West Africa⁽²⁶⁾, United States⁽²⁸⁾ and Tanzania FCT^{(Reference Lukmanji, Hertzmark and Mlingi27)}. Notably, the Tanzania FCT does not report moisture content, and concentration values for several nutrients were implausible, so that FCT was ranked fourth and used with caution. For the food items consumed that were reported in the predefined list as multiple food items (e.g. ‘Onions, tomatoes, carrots and green peppers, other viungo’), the individual foods were matched to their respective counterpart in the FCT, and the weighted mean of the nutrient values was calculated. The weights were based on the frequency of consumption reported in the Tanzania 2018 Household Budget Survey. Detailed information regarding the food matching protocol can be found in the open access repository (https://doi.org/10.17037/DATA.00004293).

To calculate the consumption of wheat flour, the quantity of wheat flour, both direct and as an ingredient in processed foods (i.e. wheat flour equivalents) such as ‘Breads’, ‘Buns, cakes and biscuits’ and ‘Sweets’, each were derived from a recipe and ingredients dataset compiled for Tanzania under the USAID Advancing Nutrition project (personal communication; Dr. Zo Rambeloson, USAID Advancing Nutrition consultant, September 29, 2023). Similarly, the consumption of cooking oil was calculated from ‘Sweets’ (i.e. sweet bakery products such as African donuts), ‘Buns, cakes and biscuits’ and ‘Breads’. Recipe and ingredient data are reported in see online supplementary material, Supplementary Table 1.

Calculation of nutrient supplies and standardisation using the adult female equivalent approach

Nutrients estimated as consumed were quantified at the household level as the sum of the quantity of each nutrient from each food item quantity multiplied by its matched composition value. Household-level nutrient supplies were standardised for comparability across households using the AFE approach. Similar to the adult male equivalent approach^{(Reference Weisell and Dop29)}, the AFE approach divides household-level nutrient supplies by the sum of AFEs based on energy requirements. The resultant unit is the supply of a nutrient per day per AFE, and this can be compared against thresholds of requirements for adult women across households. We used the AFE rather than adult male equivalent metric, to facilitate comparison against nutrient density estimates (from other studies), which are typically defined for adult women rather than men due to their higher critical nutrient density thresholds, and therefore greater risk of inadequate intake in women^{(Reference Tang, Adams and Ferguson30)}.

The AFE approach first involved calculating the total number of AFE for each household based on a reference value of estimated energy requirement of each member of the family, and divided by the energy requirement of a non-pregnant and non-lactating female aged 18–29·9 years. The energy requirements of household members were calculated according to their age and gender, estimating the activity level as ‘active or moderately active lifestyle’ (i.e. physical activity level (PAL) 1·85)⁽³¹⁾. The average weights used to calculate estimated energy requirements were obtained from anthropometric measurements in Wave 4 for females aged 0–50 years and males aged 0–15 years. Since anthropometric data for other age groups were not collected in TNPS Wave 4, the average weights of adult males (above 18 years of age) were estimated from the global database of estimated height and BMI⁽³²⁾. For males aged 16 and 17 years, weights were estimated at two midpoints between the weights of 15 and 18 years of age. The weight for females above 50 years was derived from the average weight of females aged 19–49 years measured in TNPS Wave 4. Energy requirements were estimated from non-breastmilk foods for children below 24 months by subtracting the energy from breast milk, using the energy needed from complementary foods in LMIC context (i.e. infants aged 0–2 months: 0 kilocalories (kcal)/d, 3–5 months: 76 kcal/d, 6–8 months: 269 kcal/d, 9–11 months: 451 kcal/d, 12–23 months: 746 kcal/d, estimating ‘average’ energy intakes from breastmilk)⁽³³⁾. Additional energy requirements of 500 kcal/d for lactating women were calculated as follows: women identified in the survey as being the biological mother of a child below 24 months of age were assumed as lactating women⁽³⁴⁾. This assumption was necessary because there is no information on lactation or pregnancy status of participants in TNPS Wave 4.

Estimating the adequacy of micronutrient intakes

The fixed cut-point approach was used to define the adequacy of apparent intakes at the household level for Zn, vitamin A, folate and vitamin B₁₂. Requirement values were derived from the H-AR of females aged 18–29·9 years for each nutrient^{(Reference Allen, Carriquiry and Murphy22)}. The H-AR is the intake of a nutrient that would meet the needs of half of healthy individuals in a specific life-stage group. The H-AR were as follows: Zn 10·2 mg, vitamin A 490 µg (retinol activity equivalents (RAE)), folate 250 µg (dietary folate equivalents (DFE)) and vitamin B₁₂ 2 µg^{(Reference Allen, Carriquiry and Murphy22)}. Requirements for Fe and Zn assumed ‘low absorption’ and ‘unrefined’ diets, respectively. The full probability approach was used to estimate the percentage of menstruating women at risk of inadequate Fe intakes (with 5 percent bioavailability) in women^{(Reference Allen6)}. It provides the estimated prevalence of Fe inadequacy (data not provided on the estimated range of prevalence).

We also estimated the ‘micronutrient gap’ by subtracting the H-AR for each micronutrient from the apparent intake at the 25^th percentile, to provide an approximation of the additional dietary supply of micronutrients required from fortification. The 25^th percentile of intakes was used, instead of an alternative percentile, as recommended for programmatic uses given the approximate nature of HCES intake data⁽¹²⁾.

Estimating the risk of excess micronutrient intake in large-scale food fortification

The fixed cut-point approach was used to estimate the prevalence of excess apparent intakes at the household level for Fe, Zn, vitamin A (only retinyl esters or preformed vitamin A) and folic acid. The risk of excessive intakes of folate and vitamin B₁₂ was not considered due to their low potential for toxicity and for vitamin B₁₂, the body does not store excess amounts^(35,36) . The harmonised upper limit values (H-UL), for the other nutrients, were used for females aged 18–29·9 years for each nutrient^{(Reference Allen, Carriquiry and Murphy22)}. The cut-off values of H-ULs were as follows: Fe 45 mg, Zn 25 mg (European Food Safety Authority (EFSA)) and 40 mg (Institute of Medicine (IOM) of the US National Academies), vitamin A 3000 µg retinol and 1000 µg folic acid.

Fortification scenarios

In 2021, the Tanzania Bureau of Standards was mandated to oversee food fortification (as it does with other food-related regulations) under the Finance Act 2019, and they use the East African standards to set fortificant specifications and contents⁽²⁰⁾. The standards stipulate that cooking oils should be fortified with vitamin A, with 20–40 mg RAE per kg in a retinyl palmitate form, to obtain a mean content of 25 mg/kg RE. For wheat flour and maize flour, the legislation stipulates the addition of Fe (33 mg/kg in the form of ferrous fumarate), Zn (44 mg/kg), vitamin B₁₂ (0·013 mg/kg) and folic acid (2 mg/kg, which is equal to 3·4 DFE).

In the current study, four fortification scenarios were defined to generate insights on the current and potential contribution of the national LSFF programmes towards meeting dietary requirements for these five micronutrients. To assess the current contribution of LSFF, we first defined a ‘no fortification scenario’ in which we assumed potentially -fortifiable foods contained ‘natural’ concentrations of nutrients only, as reported in FCTs and considering no fortification. We then defined a ‘status quo’ scenario, which was our best attempt to quantify apparent nutrient intakes given the current mean contents due to fortification that are observed, based on compliance with fortification standards. A market-level assessment⁽³⁷⁾ reported that only 28 percent of sampled cooking oils were fortified with vitamin A within the legislated range. Similarly, 47 percent of wheat flour was within the legislated range for Fe fortification, and none of the maize flour samples appeared to be fortified. The latter is not surprising, given that the majority of maize in Tanzania is milled at local facilities where fortification equipment is unlikely to be installed.

Two hypothetical ‘full fortification’ scenarios were then defined, to estimate the potential contribution of food fortification: (a) if all cooking oil, maize flour and wheat flour were fortified according to the specified standards and (b) if only cooking oils and wheat flour were fortified, excluding maize flour due to reach constraints. In the modelling, we assumed that all cooking oils, maize flour and wheat flour reported as consumed, in a household, were potentially fortifiable, thereby modelling, for fortification of these food vehicles, the upper limit of potential effectiveness.

The ‘status quo’ and ‘full fortification’ scenarios assumed using the values of (A) the proportion of mandatory fortification levels in 100 g of product, (B) the proportion of samples fortified to standard and (C) the expected proportion of vitamins lost between the point of production, sale and consumption^{(Reference Allen6,Reference Tang, Adams and Ferguson17)} . Table 1 describes the parameter values of the food fortification scenarios modelled. The fortification parameters were calculated as follows:

• Status quo = (A × B) × (1–C)

• Full fortification = A × (1–C)

Table 1

The parameters of food fortification in scenarios of status quo and full fortification

* 2 mg/kg of folic acid is equivalent of 3.4 mg/kg folate; the value of folic acid was used to estimate the risk of excess intakes and folate DFE was used to estimate dietary contribution.

The contribution of fortificants via wheat flour and cooking oil in products such as ‘Bread’, ‘Buns, cakes and biscuits’ and ‘Sweets’ was calculated according to recipe data (see online supplementary material, Supplementary Table 1), weighted by the ingredients of component items and included in the modelling of fortification scenarios. We did not include ‘Macaroni and spaghetti’ in this calculation because we lacked information on the amount of wheat flour produced in Tanzania that was used in the macaroni and spaghetti consumed in the country.

Data analysis

The distribution of the consumption quantities was log-transformed prior to identifying outlying values, as these were right-skewed. Outliers, which were defined as quantities >3 standard deviations from the median and missing data (0·2 percentage of the total food consumption values), were converted to the median consumption quantity of consuming households prior to further analysis.

The percentages of households reporting consumption of food fortification vehicles and the quantities consumed were reported as the median value among consumers. The reduction of the inadequacy of micronutrient intakes was calculated without changes to the proportion of the population that did not consume those foods.

Data analysis was conducted in the RStudio (RStudio 2023·06·0 Build 421, Posit Software, PBC)⁽³⁸⁾ and used several R packages: tidyverse ^{(Reference Wickham39)} for data manipulation and creating graphics and survey ^{(Reference Lumley40)} and srvyr ^{(Reference Greg Freedman Ellis, Tomasz Żółtak and Krivitsky41)} for analysing complex survey samples and calculating summary statistics of the survey data. The R code for the analysis is available open access at the following repository (https://doi.org/10.17037/DATA.00004293).