Abstract
Seasonality was shown to have an effect on food availability and accessibility, increasing the risk of food insecurity and causing poor diet quality and malnutrition. Therefore, this study aimed to determine seasonal effects on household food security status, diet quality, and nutritional status of urban poor adolescents in Malaysia. A cohort study was conducted among 164 adolescents aged 10–17 from 12 People Housing Programme in Kuala Lumpur, Malaysia during the Northeast (November 2021 till March 2022) and Southwest (June 2022 till September 2022) monsoon. Household food security status was measured using the 18-item USDA Household Food Security Survey Module. Dietary intake was determined using a two-days 24-h dietary recall and translated into Standardized Malaysian Healthy Eating Index (S-MHEI). Anthropometric and haemoglobin level measurements were performed to determine nutritional status. Seasonality was found to have a significant effect on overall diet quality (p = 0.021), food groups such as fish (p < 0.001), meat/poultry/eggs (p = 0.003), and legumes/nuts (p < 0.001), and fat nutrient (p = 0.037) as well as anaemia status (p = 0.020) after controlling the confounders. Although food security did not vary with seasons, seasonality affected the consumption of certain food groups as well as anaemia status for urban poor adolescents. Seasonally sensitive nutrition initiatives should be developed to ensure diet adherence to recommendations, ultimately enhancing the diet quality of urban poor adolescents.
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Introduction
Malnutrition in all forms remain a pervasive global issue that has yet to be fully resolved even with multiple actions by multiple sectors aimed to eradicate the problem. Almost every country in the world continues to be affected by at least a single burden of malnutrition. While anyone can suffer from malnutrition, adolescents are especially vulnerable because of their unique nutritional needs, risks, and eating behaviours as this is the period of rapid increase in both biological and psychological growth and development1. Malnutrition appears to be a matter of concern to adolescents in Malaysia2. The prevalence of stunting has decreased over the last decade, but the prevalence of thinness, overweight, and obesity has increased3, which is not on track to meet the Sustainable Development Goals (UN SDGs) and National Plan of Action for Nutrition in Malaysia (NPANM III) targets. This urges for more considerable progress in tackling the malnutrition problem among Malaysian adolescents. Besides, micronutrient deficiencies among adolescents are also a leading burden of malnutrition, causing global morbidity and mortality4. Among all, iron deficiency and iron deficiency-related anaemia account for a majority of adolescents’ disability-adjusted life years (DALY). A national longitudinal cohort study, MyHeART study, suggested an increasing trend of anaemia prevalence from 7.9% to 15.8% across the age at 13 years old to 17 years old among Malaysian adolescents5. High anaemia prevalence of 58.4% was reported in a local study among urban poor adolescents6. Anaemia is primarily attributed to micronutrient deficiencies which are particularly significant for females7. It should be highlighted that the burden of malnutrition can harm adolescents in different ways and these consequences can be associated with the early onset of chronic conditions in adulthood8,9,10.
In view to ensure optimal growth and development is attained during the adolescence period, there is an increasing need to focus on nutritional requirements and diet. The diets of adolescents have been reported as nutritionally poor and fail to meet the dietary guidelines for optimal health and well-being. Poor dietary quality is often characterized by limited diversity of food groups consumed, inadequacy of nutrients, and imbalance in dietary intake11,12. This can be observed among Malaysian adolescents who are also the most vulnerable group to have poorer diet quality associated with inadequate consumption of vegetables, milk and dairy products, and fruits as well as excessive consumption of poultry, meat, and eggs13. Poverty is also closely linked with the increased intensification of food insecurity levels and poor dietary intake. Urban poor households with low purchasing power prioritize purchasing and consuming staple foods that are perceived as cheaper and affordable but high in calories and less nutrients14. This can further worsen poor diet and nutrition outcomes among this population. In addition, a report by UNICEF15 revealed that more than 1 in 10 children aged 5 to 17 years living in low-cost flats in Kuala Lumpur have less than three meals a day and 1 in 2 households do not have enough money to buy food in the recent months. This further confirms that food insecurity is a major health-related concern in urban poor communities. Adolescents living in urban poor households who are at risk of food insecurity may be more vulnerable to undesirable and unpredictable consequences such as reduced diet quality, and consequently detrimental health status8,16,17,18.
Emerging research has highlighted the multiple direct and indirect relationships between seasonality with food security, dietary intake, and nutritional status that may occur in different combinations and for varying durations19,20,21. Seasonal variation in food accessibility and availability can also lead to changes in dietary patterns and food utilization, which in turn affects the food quantity and frequency of meals and the variety and quality of the foods people eat22,23. A Northern Bangladesh study suggested that insufficient food intake was observed during the summer season24 while an Ethiopia study showed a higher prevalence of food insecurity during wet seasons25. A neighbouring country study in Cambodia showed a higher intake of rice, starchy roots, vegetables and products, condiments, and spices was observed during wet seasons as compared to dry seasons26. A study in Northern Ghana, that looked into seasonality in food consumption, dietary diversity, and quality revealed that the intake of vitamin A-rich fruit and vegetables were higher in rainy seasons while deep yellow, orange, and red vegetables were consumed more in dry seasons27. Another study by Egbi et al.28 demonstrated the seasonality of nutritional status among Ghanaian school-age children where better height-for-age and BMI-for-age z-score were observed during wet seasons than dry seasons.
In Malaysia's context, the climate is characterized by the Southeast Asia Maritime Continent Monsoon, which consists of the Southwest monsoon (dry monsoon) that occurs from late May to September and the Northeast monsoon (wet monsoon) that occurs from November to March29,30. Global warming and climate change are becoming increasingly noticeable in Malaysia and causing rise in temperature, fluctuations in precipitation and rising sea levels31,32. These climate variability have substantial impacts on biological and agricultural systems at a range of scales and on human health and nutrition31. This impact is further exacerbated by poverty particularly among urban poor communities31. Despite the above, to date there is currently no information that provides the understanding on how seasonality affects household food security status, diet quality, and nutritional status in Malaysia. Additionally, climate change, food security, and malnutrition are now commonly regarded as high-priority objectives for many countries in terms of sustainable development, as recognized by the UN SDGs33. Therefore, it is of interest to carry out the study to determine seasonal effects on food security, diet quality, and nutritional status of adolescents in urban poor settings in Malaysia.
Results
Subject characteristics
The characteristics of the adolescents are presented in Table 1. The mean age of the adolescents was 13.2 ± 2.0 years, predominantly females (51.8%), Malay (63.4%), and receiving secondary education (57.3%) at the point of data collection. The mean monthly household income was MYR 2049.91 ± 1079.54, and the mean household size was 6.08 ± 1.45. The majority of the adolescents were in their advanced/post-pubertal stage (56.7%) and low in physical activity level (64.0%).
Seasonal differences in household food security
The subjects had a mean overall HFFS score of 5.46 ± 4.80, with 62.8% experiencing household food insecurity. The prevalence of food insecurity remains similar across seasons, with no significant differences between the Northeast monsoon (63.4%) and Southwest monsoon (62.2%; p > 0.05) (Table 2).
Seasonal differences in diet quality and its components
The mean overall S-MHEI score was 48.21 ± 10.02, which is categorized as poor diet quality. Despite the slightly higher S-MHEI score observed in the Northeast monsoon (48.57 ± 10.39) as compared to the Southwest monsoon (47.85 ± 9.64), no significant difference was observed (p > 0.05). There was a significantly higher prevalence of subjects with poor diet quality during the Northeast monsoon (66.5%) versus the Southwest monsoon (53.7%; p = 0.021). As for the components of the food group, seasonal differences were observed across the seasons where fish (4.56 ± 4.23 vs. 2.89 ± 3.54, p < 0.001), meat/poultry/eggs (8.33 ± 3.12 vs. 7.38 ± 3.57, p = 0.003), milk/milk products (1.97 ± 2.96 vs. 1.33 ± 2.16, p = 0.019) were consumed significantly more during Southwest monsoon. On the other hand, legumes/nuts (3.05 ± 4.11 vs. 1.13 ± 2.31, p < 0.001) were consumed significantly more during the Northeast monsoon. As for nutrient group components, sodium intake (7.02 ± 4.34 vs. 6.15 ± 4.62, p = 0.040) was found significantly lower during the Northeast monsoon while better adherence to optimal fat consumption was observed during the Southwest monsoon (8.44 ± 1.90 vs. 7.97 ± 1.85, p = 0.005). Other food groups such as whole grain, fruit, and vegetable consumption were notably low across both seasons (Table 2).
Seasonal differences in nutritional status
Based on the WHO classification, 13.7%, 15.9% and 21.0% of adolescents were underweight, overweight, and obese, respectively. Meanwhile, about 61.7% of adolescents were stunted. The study subjects had mean BAZ as 0.23 ± 1.93 and 0.14 ± 1.76 in the Northeast and Southwest monsoon, which significantly differed across seasons (p < 0.001). There was a significantly higher prevalence of obese adolescents during the Northeast monsoon (23.8%) as compared to the Southwest monsoon (18.3%) (p = 0.013). The prevalence of stunting was similar across seasons with no significant difference between the Northeast monsoon (9.8%) and Southwest monsoon (11.6%) (p > 0.05). In terms of haemoglobin level, more than half of the adolescents were non-anaemic with a mean haemoglobin level of 12.60 ± 8.40 g/dL and significantly higher during Southwest monsoon compared to Northwest monsoon (13.42 ± 11.73 g/dL vs. 11.77 ± 1.63 g/dL) (p = 0.001). Significant difference in the prevalence of anaemic adolescents was observed whereby higher prevalence during Northeast monsoon (50.6%; male 36.1% vs. female 63.9%) as compared to Southwest Monsoon (39.6%; male 43.1% vs. female 56.9%) (p = 0.016).
Seasonal effects on household food security, diet quality, and nutritional status
Table 3 demonstrated the seasonal effects on household food security, diet quality, and status in a Generalized Linear Mixed Model after adjusting for covariates which include adolescent’s sex, age, ethnicity, educational level and pubertal status, parental highest educational level, employment status, marital status, monthly household income, household size, and adolescent’s physical activity level. Seasonality was found to have a significant effect on overall diet quality (B(SE) = 0.58 (0.25), Wald X2 = 5.37, p = 0.021), food groups such as fish (B(SE) = -1.77 (0.42), Wald X2 = 17.77, p < 0.001), meat/poultry/eggs (B(SE) = -1.06 (0.35), Wald X2 = 9.02, p = 0.003), legumes/nuts (B(SE) = 2.14 (0.37), Wald X2 = 34.16, p < 0.001) and fat nutrient (B(SE) = -0.43 (0.21), Wald X2 = 4.36, p = 0.037). In terms of the nutritional status of adolescents, a seasonal effect was found on anaemia status (B(SE) = 0.60 (0.26), Wald X2 = 5.44, p = 0.020). No significant seasonal effects were observed among other variables (p > 0.05).
Discussion
This study showed that household food insecurity among urban poor adolescents persists throughout both seasons with similar prevalence of 63.2% and 62.2% for Northeast monsoon and Southwest monsoon, respectively. This finding was inconsistent with Ethiopia study25 and Bangladesh study34 which suggested the prevalence of food insecurity was the higher during rainy season as compared to the dry season. Despite insignificant differences in food insecurity across seasons, the high prevalence of food insecurity indicated that food insecurity remains to be a significant public health issue in the urban poor settings. Similar findings of higher prevalence of household food insecurity have been reported in previous local studies with similar study settings among low income communities16,35,36,37. The food insecurity observed among urban poor households can be due to their high vulnerability to all the uncertainties that reduces their access to safe, nutritious, and sufficient food for a healthy lifestyle14. As a result, they are forced to compromise food quantity and quality14. Urban poor households tend to rely on diets high in refined and processed foods, and fewer fresh staples such as fruits and vegetables1. According to the Adolescent Health Survey 2017, the prevalence of adolescents being hungry in Kuala Lumpur (5.7%) was found to be higher than the overall national prevalence (3.9%)38, reflecting the occurrence of food insecurity as one of the public health problems among adolescents in Kuala Lumpur.
In this study, the diet quality of urban poor adolescents was reported to be poor and none of them have the diet quality that falls under the good diet quality category. This finding was further supported by past studies16,39,40 whereby the diet quality of Malaysian adolescents was generally nutritionally poor and does not adhere to the national guidelines. Particularly, most of the adolescents failed to meet the national guidelines for all S-MHEI components except for the component of total fat intake. The consumption of vegetables, fruit, milk, and milk products, fish was below the recommended serving sizes of the national guidelines. This finding was further confirmed by other local studies16,40. The recent Adolescent Health Survey 20223 reported that four in five Malaysian adolescents does not consume enough fruits and vegetables on a daily basis. One of the possible explanations was the phenomenon of food deserts and swamps in urban food environment, whereby limited access to affordable nutritious foods and abundance of unhealthy food options can be observed41. Therefore, this is seen to be challenges to these vulnerable and disadvantaged adolescents who are living in urban poverty. Their main source of diverse food is informal food vendors which includes energy-dense street and snack foods that are readily available and accessible, which is also an affordable source of desirable and convenient calories42. Hence, limited access to nutritious food and poor dietary diversity is often observed, resulting in poor diet quality among this population.
When looking at the diet quality status, a significant difference existed between two seasons, whereby a poor diet quality was observed during the Northeast Monsoon as compared to the Southwest monsoon. This finding was further explained by the significant differences observed in S-MHEI components of fish, meat/poultry/eggs and milk/milk products, legumes/nuts, and sodium intake. These variations in dietary intake could be due to the variation in food availability and accessibility throughout the seasons. These findings were similar to previous studies where seasonal variations in dietary intake, diversity, and quality were observed in Northern Ghana27, Ethiopia25, and Western Kenya43. These countries share similar characterises of climate and geographical location with Malaysia being close to the equatorial line. Despite the similarity in the climate variability of dry and wet seasons throughout the year, variation in the staples can still be observed due to cultural differences. For example, rice is recognised as the main staple food for Malaysians44 but not in Sub-Saharan Africa countries including Kenya, Ghana and Ethiopia in which their main staple food is maize, cassava, wheat and mixed teff45,46,47. The seasonal variation in the consumption of milk/milk products and legumes in the present study was also similar to Abizari et al.27 where consumption of milk/milk products were significantly higher in the dry season whilst the consumption of legumes and nuts were significantly higher during the rainy season.
In terms of diet diversity scores, the present finding was consistent with the Ethiopia study where a higher mean diet diversity score was found during rainy seasons, indicating a better practice of a diet that compelled with national guidelines during the rainy season20. However, the present findings contradicted the findings by both Abizari et al.27 and Waswa et al.43 where a higher mean dietary diversity score with a significantly higher intake of dark green leafy vegetables and vitamin A-rich fruits and vegetables were observed during the rainy season instead. The observed seasonal differences in fruit and vegetable consumption could be explained by agriculture production activities that are highly climate-dependent, making it not readily available at all times. Low fruits and vegetables supply are often linked with increased food prices and can be a barrier to fruits and vegetables access and consumption. As a result, diet is compromised, which is particularly relevant among the urban poor population48. However, this may not apply to this study as vegetable and fruit consumption of adolescents in the present study does not differ between seasons. During the transition period, adolescents gain more eating autonomy which often opt for unhealthy diet with low fruits and vegetables consumption due to personal preferences49. Hence, the seasonality on the vegetable and fruit supply does not significantly contribute to their diet.
Findings from the present study highlight that underweight, overweight/obese, stunting, and anaemia exists in this study population, reflecting that malnutrition continues to be a public health burden in Kuala Lumpur, Malaysia. The prevalence of overweight and obesity in present study was higher than a past local study in Negeri Sembilan50 and national studies4,14. This reflected that urban poverty may possibly contribute to the increase prevalence of overweight and obesity among this population. Urban poor are more likely to confront challenges in adopting healthy lifestyle, which exposes them to long-term nutritional risk51. Besides, this study also revealed that about 45.1% of adolescents were anaemic which is much lower than findings in Kelantan (59.6%)52 and Kuala Lumpur (58.4%)6, but much higher than national prevalence (Malaysian adolescents 15–19 years old) of 20.5%53. It should be noted that the Kelantan study was carried out in rural district, where the study setting differed from the present study setting with high urbanization rate. However, both study subjects were from the same low income group (B40) and shared similar socioeconomic background. Therefore, it is still comparable and important to highlight in the present study. In addition, our finding on the anaemia prevalence is comparable to studies conducted in Indonesia (44.0%)54. A possible explanation is that adolescents are more susceptible to anaemia due to their rapid increases in physiological growth, sexual, and neurological changes that requires additional nutritional requirements55. Poor diet quality and food insecurity as indicated by the results might also be responsible for the existence of multiple forms of malnutrition in this study. While a compromised diet with inadequate nutrients intake will impede the growth and development, forced monotonous diet with high calorie can lead to overweight and obesity56. In addition, poor diet quality may contribute to poor intake of iron absorption enhancers and carriers including protein and micronutrients, subsequently resulting in low haemoglobin level57.
When comparing between seasons, a higher prevalence of overweight and obesity was observed during the Northwest monsoon compared to the Southwest monsoon. This could be partly explained by the differences in dietary intake and quality between seasons as explained above. In addition, a higher prevalence of anaemia was observed in Northeast monsoon compared to Southwest monsoon, which coincides with the decrease in the intake of iron-rich food such as meat/poultry/eggs and fish during this season as indicated in the results. This can be due to the climate variability of unprecedented major floods during Northeast monsoon that affected the production and distribution of livestock and food supplies58. Nonetheless, seasonal variation in haemoglobin level and anaemia status was not observed in the Ghana study by Egbi et al.28. This could be due to the differences in the study setting and population as the study in Ghana focuses on school age children in peri-urban communities instead.
When assessing seasonal effects using the Generalized Linear Mixed Model, seasonal effects were observed on diet quality status, S-HMEI components such as fish, meat/poultry/eggs, and legumes/nuts, as well as anaemia status after confounders: adolescent’s sex, age, ethnicity, educational level and pubertal, parental highest educational level, employment status, marital status, monthly household income, and household size were taken into consideration. Several studies have shown seasonal effects on dietary intake and diversity25,26,27,43,59 as well as nutritional status25,28,34, however, the pattern of seasonal fluctuation on dietary intake and nutritional status were shown to be inconsistent. The seasonal effects in diet quality and certain food groups influenced the seasonal effects in the prevalence of obesity and anaemia. Given that no seasonality on household food security was observed in this study, this result implies that variations in dietary quality and its components could be due the changes in either food costs or food availability of certain food source that contribute to the shift in the dietary intake and diversity32. Nevertheless, due to the study sample size, this study findings would need to be interpreted with caution. Despite inconsistencies in the findings, seasonality remains to be one of the elements to be considered in dietary intake and nutritional status considering how seasonality is an indication of climate variability which has been shown to have significant implications to food security, human nutrition and health60,61. This information serves as the basis for the establishment of various strategies and climate-sensitive policies to mitigate and address seasonal effects on food insecurity and malnutrition among urban poor communities.
This study is not without limitations. The study results may not be generalizable to other populations as the study focused on urban poor adolescents in Kuala Lumpur, Malaysia. As dietary intake and quality was assessed using a 2-day 24-h dietary recall, it may not be able to reflect the adolescent’s habitual dietary intake especially on weekdays during each season due to recall bias. Besides, additional effects of coronavirus disease 2019 including food security status, financial status, and dietary intake were not assessed suggesting further investigation is needed. The insignificant findings in the seasonal effects on household food security and nutritional status could also be attributed to the short study period and small sample size. With this, longitudinal studies with larger sample size and longer study durations of more than two consecutive years with regular follow-ups could be more informative and better reflect the seasonal effects. Future research may also consider expanding the study to urban areas of Malaysia’s East Coast (eg. Kelantan, Terengganu and Pahang) that is often affected by seasonality, which could provide a more comprehensive understanding of the seasonal effects at a national level. Despite these limitations, this study provides valuable information and contributes to the existing, yet limited literature on the seasonal effects on household food security, diet quality, and nutritional status of urban poor adolescents, in which food insecurity and poor diet quality remain appreciable concerns.
In conclusion, seasons had an effect on the consumption of fish, meat/poultry/eggs, and legumes/nuts as well as anaemia status of the urban poor adolescents. Although household food security does not vary with seasons in the present study, household food insecurity remains prevalent among urban poor communities. It is suggested that seasonally sensitive nutrition initiatives should be developed to ensure diet adherence to recommendations, ultimately enhancing the diet quality and nutritional status of urban poor adolescents.
Methods
Study design and data collection
This is a prospective cohort study that examined the seasonal variation in food security and nutritional status of the urban poor adolescents. The study protocol was previously described62. Subject recruitment was carried out from 12 People’s Housing Programme (Perumahan Awam, PA or Program Perumahan Rakyat, PPR) located in Kuala Lumpur, Malaysia, using a multistage stratified random sampling method63. There is no official definition for urban poor adolescents. For this study, urban poor adolescents are defined as adolescents who stay in PA/PPRs, an initiative by government for resettlement of urban slums to meet the housing needs of the low-income group (B40)64. Urban poor adolescents who are under any special diet or diet restriction, have chronic medical problems, are pregnant or lactating, or were infected with COVID-19 at the point of the study were excluded from the study upon recruitment. The subjects were recruited during the Northeast monsoon (November 2021) and followed up during the Southwest monsoon (June 2022) to capture a different season. Out of 663 adolescents who were invited to participate in the study, 279 adolescents consented and completed the data collection at baseline during the Northeast monsoon. Some adolescents were lost to follow-up (n = 115) during Southeast monsoon with an attrition rate of 41.2%. Only adolescents with data at both time points (n = 164) were included in the final analysis.
Ethics approval and consent to participate
The ethical approval was obtained from the Institutional Ethics Committee of UCSI University in accordance with the Declarations of Helsinki [Reference code.: IEC-2021-FAS-03)] and permission to conduct the study from Kuala Lumpur City Town Hall (DBKL) [Reference code: DBKL/JPKKB/SPZ/29–3 Jld 13 (48)] before the commencement of the study. Parents/guardians provided signed written informed consent to allow their child’s participation, and assent was obtained from adolescents to indicate their willingness to participate. The personal information of the participants will be kept anonymous and confidential.
Measures
Sociodemographic characteristics
Sociodemographic data were collected using a self-administrated questionnaire upon recruitment. Adolescent information includes age (in years), sex (male and female), date of birth, ethnicity (Malay, Chinese, Indian, and others), educational level (primary school and secondary school), and household size, whereas parental/guardian information includes, highest educational level (no formal education, primary school, secondary school, tertiary school), marital status (single, married, divorced or separated, widowed or widower), occupation (full-time work, part-time work, unemployment, retired), and monthly household income (in MYR) were collected.
Pubertal status
Pubertal Development Scale (PDS) was used to assess the pubertal status of adolescents65,66. A total of five items are assessed to rate the growth spurt, body hair growth, and skin changes using a four-point scale including not yet started (1), barely started (2), definitely started (3), seems complete (4), and I don’t know (0). On a similar scale, boys will be asked to rate their development of facial hair and voice change, whereas girls rated their breast development and whether they have reached menarche, present (4) and absent (1). Based on the sum of the scores, adolescents will be categorized into pre/early pubertal, mid-pubertal, and advanced/post-pubertal67.
Household food security status
Household food security status was assessed using the United States Department of Agriculture (USDA) 18-item Household Food Security Survey (HFSS) Module68 that captures all severity levels of food security and children’s condition in the household for both seasons. This instrument is a widely adopted tool in a variety cultural and linguistic contexts worldwide69 and been used in a national survey in Malaysia70. This section was filled by the parents or the guardians as parents or guardians will be responsible for food purchasing or preparing for the household and the adolescent. An affirmative response to each question including “yes”, “often true”, “sometimes true,” “almost every month,” and “some months but not every month” were given one point (1) and the household’s raw score was calculated. The household food security status was categorized into high food security (score = 0), marginal food security (score = 1–2), low food security (score = 3–7), and very low food security (score = 8–18). Households with high or marginal food security were categorized as food secure group, while households with low or very low food security were categorized as food insecure group68.
Dietary assessment
A two-day 24-h dietary recall of one weekday and one weekend, was used to determine the dietary intake of subjects for both seasons. Subjects were interviewed and requested to recall and describe the food items and beverages consumed 24 h preceding each of the two surveys. Detailed information including ingredients, brand names of commercial products, food preparation method as well as the portion sizes consumed with the aid of a set of standard household measurements such as spoons, teaspoons or tablespoons, cups, glasses, bowls, and plates, along with the use of the Food Atlas book71. Dietary recall data obtained were analyzed using the Nutritionist Pro® Software Version 4.0 (Axxya Systems, Stafford, TX, USA) based on the food listed in the Malaysian Composition Database Nutrient Composition of Malaysian Food. This was then further translated for the diet quality of the subjects using the Standardized Malaysian Healthy Eating Index (S-MHEI)72.
The S-MHEI consisted of 11 components, including eight food groups (total grains, whole grains, fruits, vegetables, meat/poultry/eggs, legumes/nuts, and milk/milk products) and three nutrient groups (total fat, sodium, and sugar). The scoring of these components is calculated based on the serving size and nutrient intake recommended by the Malaysian Dietary Guidelines73 and Malaysian Dietary Guidelines for Children and Adolescents74. The score of each component ranged from 0 (lack of compliance) to 10 (full of compliance), which is calculated proportionately for the in-between whole-number responses. However, as total grains and whole grains are from the same food group, the maximum score provided to each component is five to avoid scoring overlap. The total S-MHEI score was obtained by summing the scores of each component. The composite score in percentage terms was calculated using the formula: (Total Score Obtained from 11 components/10 × 100%). The possible composite score ranged from 0 to 100, in which a higher S-MHEI score indicated better diet quality. The diet quality of subjects was categorized into good diet quality (score = > 80%), diet quality needs an improvement (score = 51 – 80%), and poor diet quality (score = < 51%)72.
Anthropometric assessment
The anthropometric measurements of body weight and height of the adolescents were assessed using Bioelectrical Impedance Analyzer (OMRON HBF-375 Karada Scan Body Composition Monitor OMRON HEALTHCARE Co., Kyoto, Japan) and a calibrated vertical stadiometer (Seca 213 portable stadiometer, SECA GmbH & Co., KG. Hamburg, Germany), respectively. Both height and weight measurements were measured twice, and the mean was determined as the final measurement. The nutritional status of adolescents was determined based on Z-scores for height-for-age (HAZ) and body mass index (BMI)-for-age (BAZ) of WHO growth reference 2007 for adolescents between 5 and 19 years old using WHO AnthroPlus version 1.0.3 software (WHO, Geneva, Switzerland). The classification based on WHO growth reference charts as follows, stunting (HAZ < -2SD), normal height (HAZ > -2SD), thinness (BAZ < -2SD), normal weight (− 2SD ≤ BAZ ≤ + 1SD), overweight (+ 1SD < BAZ ≤ + 2SD), and obesity (BAZ > + 2SD)75.
Haemoglobin level test
A haemoglobin level test was performed to identify the anaemia status using the HemoCue haemoglobinometer (HemoCue® Hb 201 + System, Angelholm, Sweden), point-of-care testing on capillary blood samples. Before the blood sample collection, a brief explanation of the blood sampling method and its potential risks was provided. A drop of blood was collected and filled in the HemoCue microcuvette, and the haemoglobin result was shown within 10 min. Anaemia status and level of severity are determined according to the age and gender-specific haemoglobin cut-off point as defined by WHO76: (i) < 11.5 g/dL for 5 to 11 years of age; (ii) < 12.0 g/dL for 12 to 14years of age and non-pregnant women (15 years of age and above); (iii) < 13.0 g/dL for men (15 years of age and above).
Physical activity assessment
Physical activity questionnaire for older children (PAQ-C) was used to assess the physical activity level77. The questionnaire consisted of 10 items to assess physical activity level of subjects over the past seven days using s five-point scale ranging from ‘no activity’ scoring one, and ‘7 times or more’ scoring five. The mean PAQ-C score were calculated with range from zero (low physical activity) to five (high physical activity)77.
Statistical analysis
Statistical data analyses were performed using IBM SPSS 25.0 (SPSS Inc., Chicago, IL, USA). A test of normality will be performed using a skewness value (between − 2 and + 2) for the continuous variables involved in this study78. The descriptive analysis was used to determine mean and standard deviation (SD) for normality distributed variables, median and interquartile range (IQR) for skewed variables, and percentage and frequencies for categorical variables. A McNemar test and McNemar-Bowker test were performed to determine the seasonal differences in proportions of household food security status, diet quality status, and nutritional status across the seasons. Paired T-test and Wilcoxon signed-rank test were used to test the seasonal differences in the mean or median of household food security, diet quality, and nutritional status across seasons. The Generalized Linear Mixed Model was used to determine the seasonal effects on household food security status, diet quality, and nutritional status. The statistical significance level for all analyses was set at p < 0.05.
Data availability
The datasets used and analysed during the current study are available from JEF Tay (janicetay96@gmail.com) upon reasonable request.
References
UNICEF. The State of the World’s Children 2019. Children, Food and Nutrition: Growing well in a changing world. New York: UNICEF (2019).
UNICEF, Situation Analysis of Women and Children in Malaysia 2020. Putrajaya, Malaysia: UNICEF (2020).
Institute Public Health. National Health and Morbidity Survey (NHMS) 2022: Adolescent Health Survey 2022 Fact Sheet. Ministry of Health: Malaysia https://iku.gov.my/images/nhms-2022/2a._ahs_factsheet_bi_18052023.pdf?_t=1684481266 (2022).
Christian, P. & Smith, E. R. Adolescent undernutrition: Global burden, physiology, and nutritional risks. Ann. Nutr. Metab. 72(4), 316–328 (2018).
Krishnan, V., Zaki, R. A., Nahar, A. M., Jalaludin, M. Y. & Majid, H. A. The longitudinal relationship between nutritional status and anaemia among Malaysian adolescents. Lancet Region. Health–Western Pac. 15 (2021).
Wong, H. S. et al. Knowledge and practices in preventing nutritional anaemia of the urban poor adolescents in Kuala Lumpur, Malaysia. Nutr. Health, 1–10 (2022).
Akseer, N., Al-Gashm, S., Mehta, S., Mokdad, A. & Bhutta, Z. A. Global and regional trends in the nutritional status of young people: A critical and neglected age group. Ann. N. Y. Acad. Sci. 1393(1), 3–20 (2017).
Belachew, T. et al. Food insecurity, school absenteeism and educational attainment of adolescents in Jimma Zone Southwest Ethiopia: A longitudinal study. Nutr J. 10(1), 1–9 (2011).
Cusick, S. E. & Kuch, A. E. Determinants of undernutrition and overnutrition among adolescents in developing countries. Adolesc. Med. State Art Rev. 23(3), 440 (2012).
Patton, G. C. et al. Our future: A Lancet commission on adolescent health and wellbeing. Lancet 387(10036), 2423–2478 (2016).
Norris, S. A. et al. Nutrition in adolescent growth and development. Lancet 399(10320), 172–184 (2021).
Abdul Majid, H. et al. Dietary intake among adolescents in a middle-income country: An outcome from the Malaysian Health and Adolescents Longitudinal Research Team Study (the MyHeARTs Study). PLoS ONE 11, e0155447 (2016).
Institute Public Health. National Health and Morbidity Survey (NHMS) 2017: Adolescent Nutrition Survey (Ministry of Health, 2017).
Azizan, N. A., Thangiah, N., Su, T. T. & Majid, H. A. Does a low-income urban population practise healthy dietary habits?. Int. Health 10(2), 108–115 (2018).
UNICEF. Children Without: A study of urban child poverty and deprivation in low-cost flats in Kuala Lumpur. Putrajaya, Malaysia: UNICEF (2018).
Tay, J. E. F. et al. Food security and diet quality among urban poor adolescents in Kuala Lumpur, Malaysia. Nutr. Res. Pract. 17(2), 269–283 (2023).
Dush, J. L. Adolescent food insecurity: A review of contextual and behavioral factors. Public Health Nurs. 37(3), 327–338 (2020).
Rodríguez, L. A., Mundo-Rosas, V., Méndez-Gómez-Humarán, I., Pérez-Escamilla, R. & Shamah-Levy, T. Dietary quality and household food insecurity among Mexican children and adolescents. Matern. Child Nutr. 13(4), e12372 (2017).
Arsenault, J. et al. Seasonal differences in food and nutrient intakes among young children and their mothers in rural Burkina Faso. J. Nutr. Sci. 3, E55 (2014).
Egata, G., Berhane, Y. & Worku, A. Seasonal variation in the prevalence of acute undernutrition among children under five years of age in east rural Ethiopia: A longitudinal study. BMC Public Health 13(1), 1–8 (2013).
Stelmach-Mardas, M. et al. Seasonality of food groups and total energy intake: A systematic review and meta-analysis. Eur. J. Clin. Nutr. 70(6), 700–708 (2016).
El Bilali, H., Bassole, I. H. N., Dambo, L. & Berjan, S. Climate change and food security. Agric. For. 66(3), 197–210 (2020).
Mbow, C. et al. Food Security. In: Climate Change and Land: an IPCC special report on climate change, desertification, land degradation, sustainable land management, food security, and greenhouse gas fluxes in terrestrial ecosystems [P.R. Shukla, J. Skea, E. Calvo Buendia, V. Masson-Delmotte, H.-O. Pörtner, D.C. Roberts, P. Zhai, R. Slade, S. Connors, R. van Diemen, M. Ferrat, E. Haughey, S. Luz, S. Neogi, M. Pathak, J. Petzold, J. Portugal Pereira, P. Vyas, E. Huntley, K. Kissick, M. Belkacemi, J. Malley, (eds.)]. In press (2019).
Stevens, B. et al. The role of seasonality on the diet and household food security of pregnant women living in rural Bangladesh: A cross-sectional study. Public Health Nutr. 20(1), 121–129 (2017).
Roba, K. T. et al. Seasonal variations in household food insecurity and dietary diversity and their association with maternal and child nutritional status in rural Ethiopia. Food Secur. 11(3), 651–664 (2019).
In, S., Lambre, C., Camel, V. & Onldelhkim, M. Regional and seasonal variations of food consumption in Cambodia. Malays. J. Nutr. 22(2), 167–178 (2015).
Abizari, A. R., Azupogo, F., Nagasu, M., Creemers, N. & Brouwer, I. D. Seasonality affects dietary diversity of school-age children in northern Ghana. PLoS ONE 12(8), e0183206 (2017).
Egbi, G., Tohuoenou, M. M., Glover-Amengor, M. & Adom, T. The impact of seasonal variation on anemia and nutritional status with associated factors in 6–12 years Ghanaian school age children in peri-urban communities. Hum. Nutr. Metab. 26, 200135 (2021).
Rahman, H. A. Climate change scenarios in Malaysia: Engaging the public. IJoM-NS. 1(2), 55–77 (2018).
Tangang, F. T., Juneng, L., Salimun, E., Sei, K. & Halimatun, M. Climate change and variability over Malaysia: Gaps in science and research information. Sains Malays. 41(11), 1355–1366 (2012).
Sahani, M. et al. Impacts of climate change and environmental degradation on children in Malaysia. Front. Public Health 10, 909779 (2022).
Tang, K. H. D. Climate change in Malaysia: Trends, contributors, impacts, mitigation and adaptations. Sci. Total Environ. 650, 1858–1871 (2019).
United Nations. Transforming Our world: The 2030 Agenda for Sustainable Development. A/RES/70/1. General Assembly, Seventieth session (2015).
Hillbruner, C. & Egan, R. Seasonality, household food security, and nutritional status in Dinajpur, Bangladesh. Food Nutr. Bull. 29(3), 221–231 (2018).
Chang, A. P. Does household food insecurity reflects diet quality of children? A study among the B40 families in Pendang, Kedah. UMT J. Undergrad. Res. 2, 47–54 (2020).
Farhadian, A., Chan, V. S., Farhadian, H. & Farhadian, H. Addressing household food insecurity using the household food insecurity access scale (HFIAS) in a poor rural community in Sabah, Malaysia. Int. J. Humanit. Soc. Sci. Invent. 4, 89–100 (2015).
Ali Naser, I. et al. Association between household food insecurity and nutritional outcomes among children in Northeastern of Peninsular Malaysia. Nutr. Res. Pract. 8, 304–311 (2014).
Institute Public Health. National Health and Morbidity Survey (NHMS) 2017: Adolescent Health Survey – Key Findings (Ministry of Health, 2017).
Appannah, G. et al. Evaluation of dietary quality using Malaysian healthy eating index and its relationships with cardiometabolic risk factors in Malaysian adolescents. Malays. J. Med. Health Sci. 16, 46–55 (2020).
Rezali, F. W. et al. Evaluation of diet quality and its associated factors among adolescents in Kuala Lumpur, Malaysia. Nutr. Res. Pract. 9, 511–516 (2015).
High Level Panel Expert. Nutrition and food systems. A report by the High Level Panel of Experts on Food Security and Nutrition of the Committee on World Food Security, Rome (2017).
Gupta, V., Downs, S., Ghosh-Jerath, S., Lock, K. & Singh, A. unhealthy fat in street and snack foods in low-socioeconomic settings in India: A case study of the food environments of rural villages and an urban slum. J. Nutr. Educ. Behav. 48(4), 269–279 (2016).
Waswa, L. M., Jordan, I., Krawinkel, M. B. & Keding, G. B. Seasonal variations in dietary diversity and nutrient intakes of women and their children (6–23 months) in Western Kenya. Front. Nutr. 8, 636872 (2021).
Kasim, N. M. et al. Food choices among Malaysian adults: Findings from Malaysian adultsnutrition survey (MANS) 2003 and MANS 2014. Malays. J. Nutr. 24(1), 63–75 (2018).
Muyanga, M., Jayne, T. S., Argwings-Kodhek, G. & Ariga, J. Staple food consumption patterns in urban Kenya: Trends and policy implications (2005).
Wassie, S. B., Kusakari, H. & Sumimoto, M. Seasonality of staple food prices in Ethiopia: Does warehouse service matter?. Jpn. J. Agric. Econ. 21, 63–67 (2019).
Baffour-Ata, F. et al. Effect of climate variability on yields of selected staple food crops in northern Ghana. J. Agric. Food Res. 6, 100205 (2021).
Ellis, F. & Manda, E. Seasonal food crises and policy responses: A narrative account of three food security crises in Malawi. World Dev. 40, 1407–1417 (2012).
Neufeld, L. M. et al. Food choice in transition: Adolescent autonomy, agency, and the food environment. The Lancet 399(10320), 185–197 (2022).
Lai, W. K. et al. Prevalence and predictors of overweight and obesity among adolescents in Seremban, Negeri Sembilan, Malaysia. Cureus 14(1), e21795 (2022).
Vilar-Compte, M. et al. Urban poverty and nutrition challenges associated with accessibility to a healthy diet: A global systematic literature review. Int. J. Equity Health 20, 40 (2021).
Yusoff, H., Wan Daud, W. N. & Ahmad, Z. Nutrition education and knowledge, attitude and hemoglobin status of Malaysian adolescents. Southeast Asian J. Trop. Med. Public Health 43(1), 92–200 (2012).
Institute for Public Health. National Health and Morbidity Survey (NHMS) 2019: Vol. I: NCDs– Non-Communicable Diseases: Risk Factors and Other Health Problems. Technical Report. Institute for Public Health, Ministry of Health: Malaysia (2020).
Agustina, R. et al. Associations of knowledge, attitude, and practices toward Anemia with Anemia prevalence and height-for-age Z-score among Indonesian adolescent girls. Food Nutr. Bull. 42(1_suppl) (2021).
Das, J. et al. Nutrition in adolescents: Physiology, metabolism, and nutritional needs. Ann. N. Y. Acad. Sci. 1393(1), 21–33 (2017).
FAO/IFAD/UNICEF/WFP/WHO. The State of Food Security and Nutrition in the World 2018. Building climate resilience for food security and nutrition. Rome: FAO (2018).
Abriha, A., Yesuf, M. E. & Wassie, M. M. Prevalence and associated factors of anemia among pregnant women of Mekelle town: A cross sectional study. BMC Res. Notes 7(1), 1–6 (2014).
Mahmood, J., Rajaram, N. N. & Guinto, R. R. Addressing food insecurity and climate change in Malaysia: Current evidence and ways forward. Malays. J. Med. Sci. 29(6), 1–5 (2022).
Rossato, S. L. et al. Seasonal effect on nutrient intake in adults living in Southern Brazil. Cad. Saude Publica. 26, 2177–2187 (2010).
IPCC. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK and New York, USA, Cambridge University Press (2013).
Fanzo, J., Davis, C., McLaren, R. & Choufani, J. The effect of climate change across food systems: Implications for nutrition outcomes. Glob. Food Sec. 18, 12–19 (2018).
Tay, J. E. F. et al. Seasonal variation in food security, lifestyle, nutritional status and its associated factors of the urban poor adolescents in Kuala Lumpur, Malaysia: Research protocol of a prospective cohort study. BMC Nutr. 9(1), 24 (2023).
Sedgwick, P. Explanation for stratified cluster sampling. BMJ 347, f7016 (2013).
Khazanah Research Institute. Decent Shelter for Urban Poor: A Study of Programe Perumahan Rakyat (PPR). Kuala Lumpur: Khazanah Research Institute (2023).
Petersen, A. C., Crockett, L., Richards, M. & Boxer, A. A self-report measure of pubertal status: Reliability, validity, and initial norms. J. Youth Adolesc. 17(2), 117–133 (1988).
Chong, L. S., Chin, Y. S., Gan, W. Y. & Mohd Nasir, M. T. Associations between socio-demographic characteristics and pubertal status with disordered eating among primary school children in Selangor. Malays. Asia Pac. J. Clin. Nutr. 26(2), 326–33 (2017).
Koopman-Verhoeff, M. E., Gredvig-Ardito, C., Barker, D. H., Saletin, J. M. & Carskadon, M. A. Classifying pubertal development using child and parent report: comparing the pubertal development scales to Tanner staging. J. Adolesc. Health 66(5), 597–602 (2020).
USDA. U.S. Household food security survey module. USA: United States department of agriculture economic research service (2012) .
Marques, E. S. et al. Household food insecurity: A systematic review of the measuring instruments used in epidemiological studies. Public Health Nutr. 18(5), 877–892 (2015).
Institute Public Health. National Health and Morbidity Survey (NHMS) 2014: Malaysian Adult Nutrition Survey (MANS) Vol. II: Survey Findings. Ministry of Health: Malaysia (2014).
Suzana, S., Nik Shanita, S., Zahara, A. M. & Hasnah, H. Atlas of Food Exchange & Portion Sizes 3rd edn. (MDC Publisher, 2015).
Jailani, M., Elias, S. M. & Rajikan, R. The new standardized Malaysian healthy eating index. Nutrients 13(10), 3474 (2021).
Ministry of Health. Malaysian dietary guidelines: technical working group on nutritional guidelines (for National Coordinating Committee of food and nutrition). Putrajaya: Ministry of Health Malaysia, Nutrition Division (2020).
Ministry of Health. Malaysian dietary guidelines for children and adolescents: summary. Putrajaya: Ministry of Health Malaysia, Nutrition Division (2013).
De Onis, M. et al. Development of a WHO growth reference for school-aged children and adolescents. Bull. World Health Organ. 85(9), 660–667 (2007).
World Health Organisation. Haemoglobin concentrations for the diagnosis of Anaemia and assessment of severity. In: Vitamin and mineral nutrition information system. Geneva: WHO (2011).
Kowalski, K. C., Crocker, P. R. & Donen, R. M. The physical activity questionnaire for older children (PAQ-C) and adolescents (PAQ-A) manual. Coll. Kinesiol. Univ. Saskatchewan 87(1), 1–38 (2004).
George, D. & Mallery, M. SPSS for Windows Step by Step: A Simple Guide and Reference, 17.0 Update. 10th ed. Boston (MA): Pearson (2010).
Acknowledgements
The authors gratefully acknowledge DBKL for approval and all the relevant authorities for their efforts and time involved in the study. The authors would also like to thank the parents/guardians and subjects who agreed to participate in the study. The authors also appreciate the enumerators who were involved in the data collection.
Funding
This study is financially supported by the Ministry of Higher Education Malaysia through Fundamental Research Grant Scheme (FRGS) (FRGS/1/2020/ SKK06/UCSI/02/2). There is no involvement of the funder in the conduct of this study. The study protocol has undergone peer review by the funding body.
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J.E.F.T. was responsible for data collection, data analyses, and writing the manuscript, S.E.H.T., S.K., W.Y.G., and N.N.C. conceptualized and designed the study, provided input to data analysis, and reviewed manuscript. C.H.T. contributed to the reviewed the manuscript with substantial contribution to the interpretation of the results. All approved the final version of the manuscript.
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Tay, J.E.F., Tung, S.E.H., Kaur, S. et al. Seasonality, food security, diet quality and nutritional status in urban poor adolescents in Malaysia. Sci Rep 13, 15067 (2023). https://doi.org/10.1038/s41598-023-42394-6
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DOI: https://doi.org/10.1038/s41598-023-42394-6
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