Abstract
Purpose of Review
Because nutrition plays a crucial role in the development of chronic diseases, ensuring nutrition security is important for promoting population health. Nutrition security is defined as having consistent and equitable access to healthy, safe, affordable foods essential to optimal health and well-being. Distinguished from food security, nutrition security consists of two constructs: healthy diets and nutritional status. The study aimed to identify population measures that reflect the important constructs of nutrition security (i.e., healthy diets and nutritional status) to inform U.S. nutrition security assessment and monitoring.
Recent Findings
Through a narrative review conducted across multiple databases, associations between subconstructs of healthy diets and nutritional status were identified. Of the six subconstructs that constitute healthy diets, nutrient adequacy and moderation were most often used to assess and monitor healthfulness of U.S. population diets and were associated with health outcomes. There is little evidence of an association between health outcomes and macronutrient balance or diversity in the U.S. Thirteen instruments were identified as potentially suitable for measuring at least one subconstruct of healthy diet in the population.
Summary
This review highlights the importance of nutrition security in addressing population health challenges. It emphasizes the potential use of multiple instruments and measures to comprehensively monitor population nutrition security and inform intervention strategies. Identifying feasible and practical measures for assessing and monitoring nutrition security is imperative for advancing population health and mitigating the burden of chronic diseases.
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Introduction
Nutrition plays an important role in the etiology of several chronic diseases, including obesity, cardiovascular disease (CVD), type 2 diabetes (T2DM), and certain cancers [1]. A healthy diet consists of nutrient-dense foods across all food groups and can help minimize diet-related chronic disease risk [2]. Conversely, less healthy diets consist of high intakes of added sugars, saturated fat, and sodium, and are responsible for almost half of cardiometabolic deaths from heart disease, stroke, and T2DM in the United States (U.S.) [3]. Over 70% of U.S. adults are either overweight or obese [4] and nearly $173 billion a year is spent on health care for obesity [5]. One third of deaths in the U.S. are caused by heart disease or stroke, and the diseases cost our health care system $216 billion per year [6]. More than 37 million Americans have diabetes, and the American Diabetes Association reported the annual economic cost of diabetes in 2022 was $412.9 billion [7].
Recognizing nutrition’s role in the perpetuation of non-communicable diseases has led to the identification of nutrition security as key to addressing U.S. population health. Nutrition security is an emerging concept that places improvement of nutrition and health status within a broad population framework. It has been defined as encompassing consistent and equitable access to healthy, safe, affordable foods essential to optimal health and well-being [8]. The White House Conference on Hunger, Nutrition, and Health identified monitoring the role of nutrition to prevent and manage diet-related chronic conditions (i.e. measuring nutrition security) as a priority [9].
Nutrition security assessment and monitoring relies on availability of relevant nutritional data at the population level that highlight the dietary intake and nutritional status of individuals. Appropriate measures and indicators are essential to track the U.S.’s commitment to healthy diets in the population, advocate for healthfulness of diets, and design policies and programs to achieve these objectives. Having regularly available data for monitoring nutrition requires a coordinated system that provides information on diet, nutrition, and related health outcomes using suitable measures and indicators [10].
Nutrition security complements, but is not the same as, food security [11]. Both include a focus on food access across the population to meet energy needs [8], but nutrition security entails that nutritional needs are met alongside food access [8, 11]. Two constructs–healthy diets and nutritional status–form the basis of nutrition security. Six subconstructs support healthy diets: nutrient adequacy, nutrient density, macronutrient balance, diversity, moderation, and safety [11, 12]. The subconstructs of nutritional status are having optimal amounts in body tissues of energy, protein, essential fats, vitamins, and minerals [11]. While this framework defines constructs and subconstructs of nutrition security, we have not yet identified measures and indicators that are recognized to be suitable to assess and monitor nutrition security.
To begin addressing this gap, we must understand the extent to which existing measures and indicators are suitable for population assessment and monitoring of nutrition security generally and among vulnerable sub-populations. To be suitable, measures and indicators for assessing and monitoring nutrition security should meet the following criteria: 1) reflect important subconstructs of nutrition security; 2) associated with health outcomes; and 3) feasible for population assessment and monitoring (i.e., easy to collect and analyze within a short period of time).
The study’s aim was to identify population measures that reflect the fundamental constructs of nutrition security (i.e., healthy diets and nutritional status) to inform U.S. nutrition security assessment and monitoring. Our analysis focused on four research questions:
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1.
What is the association of subconstructs of healthy diets with subconstructs of nutritional status?
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2.
What is the association of subconstructs of healthy diets and nutritional status with food security?
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3.
What is the association of subconstructs of healthy diets and nutritional status with health outcomes?
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4.
Which simple measures and indicators of nutrition security, and combinations of them, are feasible for population monitoring?
Methods
Search Strategy
We conducted a narrative review by searching electronic databases and selecting literature to ensure a comprehensive coverage of relevant information [13]. Between October 2022 and June 2023, we reviewed peer-reviewed original research, systematic reviews, and grey literature in PubMed and Google Scholar to obtain answers to the four research questions. We developed search strategies for research questions 1–3 (Online Resource 1). For research question 4, we searched the National Cancer Institute (NCI) register of validated brief dietary assessment instruments [14].
Inclusion and Exclusion Criteria
Articles were included for the first three research questions if they met the following criteria: 1) focused on the U.S. population, 2) measured or focused on some aspect of nutrition security as conceptualized by Seligman et al. [11] (Table 1), 3) described or assessed at least one health outcome or food security, and 4) were published between 2012 and 2023. Review articles were included. Articles were excluded if they focused on food safety, a subconstruct of healthy diets, as food safety does not generally pose a widespread threat to population health in the U.S. Articles were also excluded if they focused on the subconstruct of density because it is related to the subconstruct of nutrient adequacy, and therefore it may be assessed instead of or in addition to adequacy [12]. Brief instruments were included if they were developed or validated among adults in the U.S. Brief instruments that focused only on a sub-population of U.S. adults, e.g., racial minorities, were excluded.
Data Screening
Two co-authors (E.K. & V.O.A.) screened titles and abstracts of articles independently for eligibility. Duplicates were removed. Those that remained eligible went through full-text screening.
Data Charting
We developed a data-charting table for data extraction for each research question. For research question 1, we reviewed articles reporting the relationship between the subconstructs of healthy diets and subconstructs of nutritional status. Articles were categorized by population, subconstruct of healthy diet, instrument used to measure the subconstruct of healthy diet, subconstruct of nutritional status, and associations between subconstructs of healthy diets and subconstructs of nutritional status.
For research question 2, we reviewed articles examining the relationships among food security, healthy diet, and nutritional status. The information from each article was extracted and categorized by population, subconstruct, food security measure (e.g., U.S. Adult Food Security Survey Module), and associations between subconstructs of nutrition security and food security.
For research question 3, we reviewed articles looking at the relationship between healthy diets, nutritional status, and health outcomes, extracting information separately for subconstructs of healthy diets and subconstructs of nutritional status. For healthy diets, we reviewed relevant articles and extracted information from the following categories: subconstructs measured, health outcomes measured, and associations between the subconstructs of healthy diets and health outcomes. For nutritional status, we extracted information by subconstructs, biomarker (used to measure the subconstruct), health outcome, and associations between the subconstructs of nutritional status and health outcomes.
For research question 4, we reviewed articles on brief dietary assessment instruments to determine how well they measure healthy diets (or diet quality) and their accuracy in assessing dietary data. The criteria for describing and comparing instruments were adopted from the report by the Institut de Recherche pour le Développement on healthy diet metrics [15] and encompasses the following aspects: 1) instrument, 2) assessment of healthy diet subconstruct, 3) length of measure, 4) predictive validity for health outcomes, 5) how well the instrument assesses dietary data, and 6) ease of computation.
Results
Associations between Subconstructs of Healthy Diets and Subconstructs of Nutritional Status
Using different dietary assessment instruments, studies among U.S. adults investigated the relationship between some of the subconstructs of healthy diets (diet diversity, moderation, nutrient adequacy), and nutritional status captured via anthropometry (e.g., body mass index, waist circumference, percent body fat); and the subconstructs of healthy diets and specific biomarkers (e.g., serum cholesterol). Healthy diet subconstructs were assessed via different instruments including the Healthy Food Diversity (HFD) index, Healthy Eating Index (HEI) (1995, 2010 and 2015 versions), and Sustainable Diet Index (SDI)-US. Higher scores on the HFD index (which captures dietary diversity) were associated with lower risk of adiposity or obesity [16]. Studies using the HFD index found lower odds of obesity, android-to-gynoid ratio, and fat mass index (FMI), and lower odds of elevated waist circumference among men and women with the highest quality diet compared to the lowest [16, 17]. Higher scores on the HEI (which captures nutrient adequacy and moderation) were associated with reduced risk of abdominal and central obesity, lower percentage body fat, and lower fat mass index [18,19,20]. A higher SDI score captured nutrient adequacy and was also associated with lower odds of obesity (Table 2). These findings indicate an association between the subconstructs of healthy diets and nutritional status as higher scores on indices of healthy diets are associated with lower risk of adiposity (i.e., obesity and percentage of body fat).
Associations Between Food Security and Nutrition Security
In the U.S., both food-secure and food-insecure individuals have poor diets [22, 23]. For the subconstructs of healthy diets, macronutrient intakes did not differ when comparing food-secure and food-insecure individuals, but food-insecure individuals were at higher risk of inadequacy for some micronutrients. Among food-insecure men and women, lower intake was found for magnesium, potassium, vitamins B6, C, and D, when compared to food-secure men and women [24]. A systematic review of food insecurity and diet quality found no evidence of an association between food insecurity and intake of carbohydrates or protein and limited evidence of adverse associations with total fat or fiber, with mixed evidence concerning intake of saturated fat [25]. There were, however, associations across samples of varying age and sex between food insecurity and inadequate intakes of calcium, magnesium, and zinc (Table 3).
The literature provides limited evidence regarding associations between the subconstructs of nutritional status and food security. In some studies, U.S. adults show positive associations between food insecurity and obesity, with stronger associations observed in women [26, 28, 34]. Researchers investigating the connection between food insecurity and inflammation found that food insecurity was linked to higher levels of C-reactive protein with an adjusted odds ratio of 1.21 [29]. Furthermore, a study focusing on the association of food insecurity with nutritional biomarkers in U.S. children revealed no difference in vitamin D, zinc, and iron status between food-secure and food-insecure children [30]. The associations between the subconstructs of nutritional status and food security have not been extensively studied in U.S. adults.
Associations Between Subconstructs of Healthy Diets and Nutritional Status with Health Outcomes
Healthy Diets
The adequacy and moderation subconstructs of healthy diet are associated with health outcomes (Table 4). There is less evidence of an association between macronutrient balance or diversity and health outcomes. Most U.S. studies relied on the HEI and Alternate Healthy Eating Index (AHEI) to measure the healthfulness of diets. These indices, along with several others, are primarily constructed to assess adherence to a particular diet (e.g., Dietary Approaches to Stop Hypertension (DASH) score) or dietary guidelines (e.g., HEI). They also encompass measures of adequacy, moderation, and density. The AHEI was developed to better predict health outcomes when compared to the HEI [35,36,37], but there were no important differences between the associations from the HEI and AHEI with health outcomes [38, 39]. Both the HEI and AHEI are correlated with chronic diseases. Higher scores on both indices are associated with reduced risk of all-cause mortality, cancer, CVD, T2DM, and other chronic diseases (Table 4). The Dietary Patterns Methods Project synthesized that higher diet quality as measured via the HEI, AHEI, alternate Mediterranean diet score, and the DASH score was associated with an 11–28% reduced risk of death due to all-cause, CVD, and cancer when compared to the lower diet quality [40].
Nutritional Status
Energy, a subconstruct of nutritional status, is associated with health outcomes. Excess energy has been linked with adverse health outcomes including obesity, CVD, T2DM, cancer, osteoporosis, and osteoarthritis [54]. Most adults obtain sufficient protein through their diets. There is insufficient evidence to suggest that excess protein intake leads to adverse health effects [55]. There is evidence, however, that long-term consumption of red meat and processed meat is associated with an increased risk of total mortality, CVD, colorectal cancer, and T2DM [56, 57]. Diets high in saturated fats are linked to higher mortality rates from all causes, CVD, and cancer. In contrast, diets rich in polyunsaturated and monounsaturated fats are associated with lower all-cause mortality [58].
The Dietary Guidelines for Americans identified nutrients or vitamins and minerals of public health concern for individuals aged one year and older. The nutrients of concern include low intakes of fiber, calcium (for individuals aged 2 years and older), vitamin D, and potassium. Excessive nutrient intake is a concern for sodium, added sugars, and saturated fats (for individuals aged 2 years and older). These nutrients have been associated with adverse health consequences [59]. For sodium, high intakes above recommendations have been associated with higher risks of hypertension and cardiovascular diseases [60, 61]. Both suboptimal and excessive intakes of nutrients such as calcium, iron, vitamin D, and potassium are associated with health outcomes like hypertension and coronary heart diseases [62,63,64] (Table 5). For instance, suboptimal vitamin D concentrations are associated with higher risks of CVD, hypertension, cancer, T2DM [63]; while excessive intake of calcium supplements is associated with increased risk of cardiovascular diseases, including coronary heart disease and myocardial infarction [64, 65].
Summary of Instruments
Twenty-four-hour dietary recall is a standard method to obtain dietary data but is difficult to collect and analyze for timely population-level monitoring. Thus, instruments that measure the relevant subconstructs of healthy diets and nutritional status and are valid and reliable on a population basis are needed for timely population-level assessment and monitoring of nutrition security. The following is a list of potential instruments that may be used to assess and monitor the subconstructs of nutrition security.
Healthy Diets
We identified 13 brief dietary instruments out of 63 brief dietary instruments in the National Cancer Institute registry that measured at least one subconstruct of healthy diets and can be used for population assessment and monitoring (Table 6). Three brief dietary instruments developed and validated for global use were also included.
These brief instruments have between six and 26 items administered as a short food frequency questionnaire, food checklist, or behavioral questionnaire about dietary practices. Most instruments measure frequency of consumption of specific foods or food groups in the past month [14]. An exception is PrimeScreen, an instrument that captures the frequency of consumption of certain food groups over the previous year using five categories of frequency of consumption: less than once per week, once per week, two to four times per week, nearly daily or daily, or twice or more per day [97, 98].
While some brief instruments were inclusive of food groups or dietary components [14], others were specific to fruits and vegetables [94]. For example, the Dietary Screener Questionnaire (DSQ) is a 26-item instrument to capture intakes of fruits and vegetables, dairy/calcium, added sugars, whole grains/fiber, red meat, and processed meat. The Behavioral Risk Factor Surveillance System (BRFSS) fruit and vegetable brief instrument, however, has just 6 items on fruit and vegetable intake frequency.
Some brief instruments (e.g., DSQ) have been used in national surveys like the National Health and Nutrition Examination Survey (NHANES) and the National Health Interview Survey (NHIS) [14]. The Prime Diet Quality Score (PDQS), Global Diet Quality Score (GDQS), and Global Dietary Recommendation (GDR) score have been used for global assessment and to distinguish between healthy and unhealthy components using difference scores (i.e., scores that combine both positive (healthy) and negative (unhealthy) components of an instrument to create a total score). Others (e.g., Starting the Conversation or Rapid Eating and Activity Assessment for Participants-Short) were designed and validated for clinical settings [101, 103].
Most brief instruments were validated against standard food frequency questionnaires and/or 24-h recalls to determine how well they measured dietary data (Table 6). Correlations with the standard instruments were reported. While some instruments had modest correlations with standard instruments [94, 97], others underreported some dietary components compared to standard instruments [14]. Few of the identified brief instruments have been examined for predictive validity for health outcomes [96].
The three brief instruments developed for global use measure more healthy diet subconstructs compared to other brief instruments. The GDQS measures nutrient adequacy, diversity, and moderation [42], whereas the GDR score measures nutrient adequacy, nutrient density, diversity, and moderation [105]. The GDQS can be collected using a full 24-h recall but does not require quantifying and converting foods into nutrient values, making data cleaning and processing simpler. The instrument can also be used via an electronic app that provides standard, easy-to-use methods for collecting low-cost, time-relevant data on diet quality. For the ease of data collection, the GDR score relies on a questionnaire that gathers simple information on consumption (yes/no) of a limited number of food groups (or sentinel foods representing those food groups), which allows a short interview time (from 3 to 6 min) and does not require interviewers to have specific training [15].
Nutritional Status
There are a range of methods for measuring the subconstructs of nutritional status, including anthropometric, body composition, clinical, and biomarker measures. These include several different techniques for measuring body composition, including anthropometry, dual-energy X-ray absorptiometry (DEXA), and bioelectrical impedance analysis (BIA). DEXA and BIA are valid measures of body composition at the population level, but not feasible for population data collection [54, 66]. Body mass index (BMI) is a widely used anthropometric measure related to body composition that predicts mortality of adults at the population level, but BMI does not differentiate between body lean mass and body fat mass [107,108,109]. Potential biomarkers for assessment of red meat are 13C, 15N, Creatinine, Taurine, 1-methylhistidine, and 3-methylhistidine [56, 57]. For fats, it may be useful to measure polyunsaturated fats, monounsaturated fats, and saturated fats via red blood cell, plasma phospholipids, and cholesterol esters [57, 58].
Calcium levels in the blood are responsive to hormonal regulation rather than dietary intake. Therefore, monitoring serum calcium levels will not accurately capture changes in dietary calcium intake. Dietary calcium intake is related to bone health. Measuring biomarkers of bone remodeling (e.g., tartrate-resistant acid phosphatase, procollagen type, osteocalcin) should determine the role of dietary intake of calcium on bone health at the population level [81]. It may also be appropriate to assess dietary intake of calcium to assess adequacy of calcium intake. For vitamin D, serum 25-hydroxy vitamin D level is an appropriate biomarker to assess vitamin D levels in the blood, as the levels are reflective of dietary intake of vitamin D and sun exposure. This biomarker is not appropriate to assess bone loss due to deficient vitamin D intake [81, 110]. For potassium, blood (serum) potassium concentrations and hypokalaemia are not reliable measures of usual potassium intake or status in the healthy population. Therefore, assessing dietary intake of potassium is more appropriate to determine adequacy of potassium intake [111]. Assessing urinary excretion of sodium, especially over a 24-h period, is an appropriate biomarker for dietary sodium intake at the population level [112]. Lastly, higher consumption of heme iron is associated with higher levels of serum ferritin and hemoglobin levels. Serum ferritin as a biomarker reflects adequate dietary intake of iron, especially heme iron, and is appropriate to assess adequacy of iron intake at the population level [62].
Discussion
Nutrition plays a pivotal role in the prevention and management of many chronic diseases, prompting the emergence of nutrition security as an essential component in improving population health. Distinguished from food security, nutrition security encapsulates not just access to food but ensuring that food accessed and consumed meets nutritional needs, which is the basis for the subconstructs of healthy diets and nutritional status [11]. To inform U.S. nutrition security measurement needs, our study aimed to identify measures at the population level that reflect important subconstructs of healthy diets and nutritional status. To assess key subconstructs for population monitoring, we reviewed associations between healthy diet and nutritional status, as well as their associations with food security and health outcomes. These findings then laid the foundation for identifying feasible measures and indicators crucial for assessing and monitoring nutrition security.
Some biomarkers might be useful in monitoring nutrition security. For some nutrients, like iron, assessing only subconstructs of healthy diets is sufficient because biomarkers (e.g., serum ferritin) are associated with dietary intake. For other nutrients such as calcium, biomarkers (e.g., serum calcium) are not associated with dietary intake; nevertheless, it may be useful to monitor some biomarkers such as those of bone remodeling that are related to calcium functions in the body, specifically bone health and potentially predictive of health outcomes such as osteoporosis. Measuring all the subconstructs of healthy diets and nutritional status may be ideal but is not practical for population-level monitoring due to time and financial constraints.
Food security is associated with some, but not all subconstructs of nutrition security. For example, in the U.S., limited evidence links food insecurity to specific macronutrient intake differences, although studies highlight associations between food insecurity and lower intakes of calcium, magnesium, and zinc across various age groups and genders. Research in U.S. adults indicates positive association between food insecurity and obesity in some sub-populations and with higher levels of C-reactive protein. While there are associations between food security and certain subconstructs of nutrition security, monitoring both will be important. Nutrition security offers insights that food security alone cannot provide.
Of the six subconstructs identified to constitute healthy diets [11], our review found that nutrient adequacy and moderation were most often used to assess and monitor healthfulness of U.S. population diets and were associated with health outcomes. There is little evidence of an association between health outcomes and macronutrient balance or diversity in the U.S. since most research relies on HEI/AHEI and neither HEI nor AHEI captures these two subconstructs. Further research is needed to relate macronutrient balance and diversity to U.S. population health outcomes.
Various data systems and several instruments are used for dietary assessment. Data systems include the NHANES, the NHIS, and the BRFSS. Indices that are used frequently in the U.S. are the HEI and the AHEI. While HEI is obtained through NHANES data, and frequently utilized in research, data from NHANES has been released to the public every other year, and there can be a substantial lag before that data is publicly available. It may be more opportune to utilize HEI data in combination with a brief instrument or instruments that could be incorporated into other surveys (e.g., NHIS), where data may be released more promptly. Possible existing instruments include the GDQS, GDR score, PDQS, and the BRFSS fruit and vegetable instrument. The GDQS, GDR score, and PDQS also measure healthy and unhealthy food consumption. This may inform policies and programs to promote healthier foods and curb unhealthy food consumption. Further research is required to understand the predictive validity of these brief instruments in relation to health outcomes. Additionally, it is essential to investigate possible differences in the association of unhealthy foods (moderation) and health outcomes vs. healthy foods (adequacy) and health outcomes (i.e., risk reduction).
An ideal nutrition security system for population-level assessment and monitoring should encompass several elements to ensure comprehensive and effective tracking and intervention strategies. The first is regular data collection. There is a need for regular and standardized data collection mechanisms to monitor nutrition security across different demographic groups and geographic regions. This may require multiple data sources, including surveys (e.g., NHANES, NHIS), health facilities, school records, and community health workers to gather comprehensive data. There may be value in linking multiple data sources, or at least making use of multiple different sources, as the 1990 National Nutrition Monitoring and Related Research Act did in bringing together multiple sources of data on nutrition monitoring from federal agencies and state and local governments [10]. Rapid data collection and reporting that leverages the use of technology, can help enable timely reporting and interventions.
The next element is the measure of subconstructs of healthy diets and, if appropriate and possible, nutritional status, as well as monitoring health outcomes of importance, including obesity, CVD, T2DM, and other related health conditions. Nutrition-related chronic diseases often have associated biomarkers that are distinct from traditional measures of nutritional status. For instance, blood pressure, a biomarker for hypertension, does not inherently reflect nutritional status or dietary intake. Similarly, biomarkers like blood glucose levels and HbA1C play roles in diagnosing and monitoring diabetes but do not inherently reflect nutritional status or dietary intake. Measures like these may be helpful in monitoring nutrition security because they tell us about important consequences of nutrition-related chronic conditions.
For measures of healthy diets, adequacy and moderation independently and potentially differentially affect health outcomes. Adequacy is focused on having enough important nutrients in the diet, which may decrease risk of particular health outcomes, whereas moderation is focused on moderating the amounts of unhealthy constituents in the diet, which can increase risk of poor health outcomes. It will be important to track metrics for each of these two subconstructs separately rather than using the difference between the two metrics. Using difference scores in dietary data is not ideal due to overestimation of total scores, ambiguous interpretation (i.e., midrange scores that can have various contributing components resulting in different dietary patterns), low reliability, discarded theoretical information, and discriminant validity issues [39, 113, 114].
Another essential element for a nutrition security system is data dissemination and transparency. Nutrition security data and assessment results should be publicly available to encourage transparency and accountability, and will include effective communication of findings to policymakers, healthcare providers, and the public [115, 116]. The last element is regular evaluation and adaptation of the nutrition security system. Incorporating feedback from stakeholders and communities to improve the system over time, along with continuous evaluation of the system’s effectiveness and adaptability to changing circumstances will be necessary to ensure useful assessment and monitoring. By incorporating these elements into a nutrition security system, policymakers and stakeholders can better understand the nutritional needs of the population and implement targeted interventions and policies to improve nutrition outcomes at the population level.
Several lines of research would be particularly helpful in further developing nutrition security monitoring. First among these is how measures and indicators can capture and reflect disparities in nutrition security across diverse populations. Understanding how various factors such as socio-economic status, geographical region, and cultural background intersect with nutrition security is paramount in developing tailored interventions and policies that can effectively target vulnerable sub-populations. Another priority for research will be the ongoing validating and updating of measures to reflect changes in nutrition security over time. It is essential to consider whether these updates should coincide with guidelines, like the Dietary Guidelines for Americans, to ensure that our measures align with the latest nutritional recommendations. Finally, the question of how these measures should be communicated and utilized remains central. Effective communication and utilization are critical in informing policy decisions, interventions, and resource allocation. In this context, the journey to understanding and improving nutrition security is dynamic and evolving and will require continued attention, research, collaboration, and innovation.
Conclusion
This analysis outlined the relationship between subconstructs of healthy diets, subconstructs of nutritional status, food security, and health outcomes. The interplay among these highlights the complex understanding of nutrition and its impact on population well-being. The pursuit of feasible and practical measures and indicators for nutrition security monitoring and assessment is a critical challenge. These metrics serve as the foundation for evidence-based policy development and program design, enabling monitoring of progress towards ensuring the attainment of healthful diets for all. The complexity of these associations necessitates an ongoing commitment to research, monitoring, and the implementation of data-driven strategies that can ultimately enhance the health and well-being of our communities.
Data Availability
No datasets were generated or analysed during the current study.
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Acknowledgements
This research was supported by the US Department of Agriculture, Economic Research Service Strategic Priority Grant program though cooperative agreements 58-4000-1-0093 with the University of California San Francisco (H.K.S., Principal Investigator) and 58-4000-1-0084 and 58-4000-2-0054 with the University of South Carolina (E.A.F., Principal Investigator).
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Open access funding provided by the Carolinas Consortium. Economic Research Service, United States, 58-4000-1-0084, 58-4000-1-0093.
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All authors contributed to the study conception and design. Material preparation, data collection and analysis were performed by E.K. and V.O.A. The first draft of the manuscript was written by E.K. and V.O.A. and all authors commented on previous versions of the manuscript. A.C.-J. and E.A.F. acquired the funding. E.A.F. provided supervision. All authors read and approved the final manuscript.
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Kenney, E., Adebiyi, V.O., Seligman, H.K. et al. Assessing and Monitoring Nutrition Security in the United States: A Narrative Review of Current Measures and Instruments. Curr Nutr Rep 13, 639–667 (2024). https://doi.org/10.1007/s13668-024-00547-7
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DOI: https://doi.org/10.1007/s13668-024-00547-7