This paper is in the following e-collection/theme issue:

Digital Health Reviews (1758) Innovations and Technology for Healthy Eating Education (496) Chronic Conditions (448) mHealth for Symptom and Disease Monitoring, Chronic Disease Management (1762) mHealth for Wellness, Behavior Change and Prevention (3356)

Published on in Vol 28 (2026)

Preprints (earlier versions) of this paper are available at https://preprints.jmir.org/preprint/77726, first published .
Diet-Related Health Recommender Systems for Patients With Chronic Health Conditions: Scoping Review

Diet-Related Health Recommender Systems for Patients With Chronic Health Conditions: Scoping Review

Diet-Related Health Recommender Systems for Patients With Chronic Health Conditions: Scoping Review

Authors of this article:

Xiaolan Dong1 Author Orcid Image ;   Bei Yun2 Author Orcid Image ;   Anni Pakarinen1, 3 Author Orcid Image ;   Zhuting Zheng2 Author Orcid Image ;   Hao Niu2 Author Orcid Image ;   Tian Jin2 Author Orcid Image ;   Changrong Yuan2 Author Orcid Image ;   Jingting Wang4 Author Orcid Image
Article Authors Cited by Tweetations Metrics

    1Department of Nursing Science, University of Turku, Turku, Finland

    2School of Nursing, Fudan University, Shanghai, China

    3Faculty of Nursing and Physiotherapy, University of Lleida, Lleida, Spain

    4School of Nursing, Naval Medical University, 800 Xiangyin Road, Shanghai, China

    *these authors contributed equally

    Corresponding Author:

    Jingting Wang, PhD


    Background: Diet-related Health Recommender Systems (HRSs) have gained attention for their potential to provide personalized dietary guidance, particularly for patients with chronic conditions. However, studies on diet-related HRSs in health care are relatively limited.

    Objective: This scoping review aims to present the state of current research on diet-related HRSs for patients with chronic health conditions, identify existing gaps, and suggest future research directions.

    Methods: The scoping review was conducted following the Arksey and O’Malley framework and was reported in accordance with the PRISMA-ScR (Preferred Reporting Items for Systematic Reviews and Meta-Analyses Extension for Scoping Reviews) guidelines. The literature search was conducted in October 2024 across 6 English databases (PubMed, Medline, Embase, Web of Science Core Collection, IEEE Xplore, and CINAHL) and 4 Chinese databases (SinoMed, CNKI, Wanfang, and VIP). Studies focusing on diet-related HRSs for patients with chronic conditions were included.

    Results: Fifteen studies published between 2010 and 2024 from 9 countries were included. Diet-related HRSs mainly target adults with chronic diseases, with 9 systems (60%) including users with diabetes and 6 (40%) including users with hypertension. Nine studies (60%) described functional structures, which were categorized into 4 components: user information, food or diet recommendations, knowledge and decision support, and data management with additional functions. Recommended content was categorized into 5 types: food (n=6, 40%), recipes (n=4, 26.67%), diet plans or meal plans (n=3, 20%), recipes and food (n=1, 6.67%), and meals (n=1, 6.67%). Recommendation methods included constraint-based (n=6, 40%), focusing on patients’ dietary restrictions; preference-based (n=5, 33.33%), considering patients’ food preferences; and hybrid (n=4, 26.67%), combining both approaches. Of all recommendation technologies, most studies (n=13, 86.67%) applied hybrid approaches, enabling more robust personalization. For the data used for training, 13 studies (86.67%) explicitly mentioned the data sources, and 10 studies’ (66.67%) data came from professional organizations and websites. The recommendation process followed a structured workflow. Twelve studies (80%) evaluated diet-related HRSs using either online or offline methods, while accuracy (n=9, 60%) has been the most common evaluation criterion. However, no studies went deeper into how these systems affected users’ dietary behaviors over time.

    Conclusions: Diet-related HRSs have the potential to deliver personalized dietary support for patients with chronic diseases, but current systems show key gaps. Future development must adopt user-centered design, provide practical and actionable dietary guidance, and use hybrid recommendation techniques to increase precision and clinical relevance. Standardized evaluation methods and real-world, long-term studies are essential to evaluate the impact of diet-related HRSs on dietary behavior and health outcomes. Addressing these needs will enable diet-related HRSs to become reliable tools for chronic disease management and patient-centered care.

    Trial Registration: International Platform of Registered Systematic Review and Meta-analysis Protocols INPLASY202550081; https://inplasy.com/wp-content/uploads/2025/05/INPLASY-Protocol-7837.pdf

    J Med Internet Res 2026;28:e77726

    doi:10.2196/77726

    Keywords

    Health Recommender SystemDiet-related Health Recommender Systemchronic health conditionsdietscoping reviewPRISMAHRS 


    Dietary management is crucial to overall health, especially in the context of global trends where poor dietary habits have become a significant factor contributing to weight-related issues [1]. Statistics from the latest Global Nutrition Report indicated alarming rates of overweight and obesity among adults, with 40.8% of adult (18 years or older) women and 40.4% of adult men affected. Conversely, 9.1% of adult women and 8.1 % of adult men were underweight [2]. Improper dietary management not only affects body weight but also contributes to the development of diabetes [3,4], hypertension [5], cardiovascular diseases [6], chronic kidney disease [7], and inflammatory bowel disease [8], among others.

    The Scientific Research Report on Dietary Guidelines for Chinese Residents (2021) highlighted that the overweight and obesity rates among children younger than 6 years old and those aged 6‐17 years were 10.4% and 19.0%, respectively [9]. Among residents aged 18 years and older, the overweight rate was 34.3% and the obesity rate was 16.4%, with 50.7% of adults being overweight or obese [9]. Overweight and obesity are significant risk factors for cardiovascular diseases, diabetes, cancer, and other chronic health conditions [9].

    Poor dietary habits contribute to both the onset and progression of these chronic conditions. Therefore, scientific and effective diet management is essential for ensuring proper nutrient intake, which directly enhances individual immunity, halts disease progression, impacts health status, and supports recovery from chronic health conditions, thereby improving overall health outcomes [7,10,11]. Moreover, good diet management regulates sleep and mood, reduces fatigue, and comprehensively enhances overall health [12,13]. In February 2024, China’s National Health Commission released the “Dietary Guidelines for Adults with Hyperuricemia and Gout (2024 Edition),” “Dietary Guidelines for Adult Obesity (2024 Edition),” “Dietary Guidelines for Childhood and Adolescent Obesity (2024 Edition),” and “Dietary Guidelines for Adults with Chronic Kidney Disease (2024 Edition)” [14]. These guidelines aim to prevent and control the occurrence and progression of chronic diseases among the Chinese population through dietary management.

    Patients with chronic health conditions often need to adjust their diets based on their specific health status to manage health conditions effectively and enhance the overall quality of life. When patients are required to follow dietary restrictions due to their chronic health condition, it is important for the patient to distinguish whether certain foods are permissible, ensure that the cooking methods meet the essential requirements, evaluate whether portion sizes are appropriate, and strive to maintain a balanced diet to reduce the risk of malnutrition and other issues caused by dietary limitations [15]. Therefore, these patients require targeted and personalized guidance to help them implement scientific and feasible dietary management practices.

    Recommender Systems (RSs) are software tools that provide suggestions or recommendations of items to users, such as products, services, information, or content, based on their preferences, interests, and past behaviors [16], which have been used in several domains such as e-commerce, e-learning, e-tourism, or eHealth. To generate recommendations, RSs commonly rely on a set of foundational recommendation technologies. Collaborative filtering (CF) is one of the most widely applied recommendation technologies, which provides recommendations for users by using the known preferences of other users with similar behaviors [17]. In contrast, content-based (CB) methods recommend items similar to those a given user has previously liked [18]. Unlike CF and CB, which rely on large historical rating datasets, knowledge-based (KB) approaches produce suggestions by leveraging domain knowledge, expert rules, and explicit user constraints [19]. Knowledge graph (KG)-driven recommendation further enhances personalization by representing domain knowledge in graph structures to generate precise suggestions [20]. Finally, hybrid recommendation (HyR) integrates 2 or more strategies to maximize their strengths and mitigate individual limitations [21].

    Health Recommender Systems (HRSs) are also one of the RS’s important application scenarios. HRSs offer the potential to motivate and engage users to change their behavior by sharing better choices and practical knowledge based on observed user behavior [22]. HRSs have been applied in health care in recent years, in areas such as mental health [23], hearing aid usage [24], health education [25], physical activity [26], and diet-related health [27].

    Diet-related HRSs are software tools that use personalized data to provide tailored food recommendations from a wide range of options [28]. Diet-related HRSs present promising solutions to the issues of information overload and limited food choices, which contribute significantly to diet-related health problems [29]. By using personalized data, diet-related HRSs offer tailored food recommendations that take into account users’ taste preferences, dietary needs, and medical conditions [30]. Such systems can filter and sort food options [27], fostering a better understanding of dietary health and increasing user engagement [31]. Additionally, diet-related HRSs can enhance dietary outcomes by providing nutrition assessments and offering healthier meal plans and recipes [28].

    While diet-related HRSs have been explored within the field of information and communication technology, research on their application in chronic disease dietary management is still limited, and there is a lack of comprehensive literature reviews in this area. To address these gaps, this study adopted a scoping review methodology to review the research status quo of diet-related HRSs for individuals with chronic conditions. In this review, diet-related HRSs are defined as systems specifically designed for patients with chronic health conditions that require disease-related dietary restrictions. The target populations, function structures, recommendation content, implementation of recommendation features, and evaluation of the diet-related HRSs were analyzed to provide a reference for health care researchers seeking to design more effective and user-friendly systems.


    Overview

    Scoping reviews assess the extent of the research, range, and nature, identify gaps, determine systematic review value, and disseminate research findings [32]. A scoping review methodology is used to systematically map available research on the broad, complex, and emerging research question [32]. In emerging research fields, a lack of randomized controlled trials may impede formal systematic reviews or meta-analyses. Scoping studies can address diverse questions and incorporate a range of study designs, making them ideal to complement clinical trial findings. The scoping review was conducted following the Arksey and O’Malley framework [32] and was reported in accordance with the PRISMA-ScR (Preferred Reporting Items for Systematic Reviews and Meta-Analyses Extension for Scoping Reviews) guidelines [33] and was structured according to the following outlined steps.

    Stage 1: Identification of the Research Question

    The research question was identified after an initial review of the literature and a discussion within our research team. The key research questions that guided the review were as follows:

    1. What is the current state of research on diet-related HRSs for patients with chronic health conditions?
    2. What are the target users for diet-related HRSs for patients with chronic health conditions?
    3. What are the function structures in diet-related HRSs for patients with chronic health conditions?
    4. What types of recommendation content are provided by diet-related HRSs for patients with chronic health conditions?
    5. How are recommendation features implemented in diet-related HRSs for patients with chronic health conditions?
    6. How are diet-related HRSs for patients with chronic health conditions evaluated?

    Stage 2: Identifying Relevant Studies

    Before searching, the research team worked collaboratively in making decisions about inclusion and exclusion criteria and in planning the initial search strategies to comprehensively identify the relevant literature. The final search strategies were developed with the assistance of a health science librarian (Multimedia Appendix 1). The literature search was performed by 3 researchers in October 2024, covering 6 English databases (PubMed, Medline, Embase, Web of Science Core Collection, IEEE Xplore, and CINAHL) and 4 Chinese databases (SinoMed, CNKI, Wanfang, and VIPC). Relevant studies were searched from January 2010 to October 2024 to answer the above research questions (1-6). An example of the search strategy performed in Web of Science Core Collection is presented here: (recommender system* OR hybrid recommendation* OR collaborative filtering OR content based recommendation* OR recommendation* system* OR knowledge based recommendation*) AND (recipe* OR diet* OR food OR eat* OR nutrition*). As the search proceeded, additional terms were suggested by experts to potentially modify the question, but new research did not result in additional data, and the question did not change. Duplicate references were filtered out using EndNote. In addition to database search, hand searching was conducted by screening the reference lists of all included articles and relevant review papers to identify additional eligible studies. We also manually checked key journals in the field and conference proceedings to ensure comprehensive coverage.

    Stage 3: Study Selection

    All studies searched were independently assessed by 2 authors (XD and BY) based on the inclusion criteria listed below, and discrepancies were verified by a third author (JW). Studies were eligible for inclusion in this review if all the following criteria were met: (1) the recommended information was related to at least one of the following: food, meal plan, diet plan, and recipe; (2) the study applied personalized recommendation strategy; (3) the recommendations were generated using algorithmic and technological methods; (4) the study population comprised patients with chronic health conditions; and (5) the study was published in a peer-reviewed journal or conference proceeding. The exclusion criteria included: (1) the recommendation unrelated to human health (eg, study focusing on animal health [34]), (2) studies reporting the same RSs were considered duplicates; only the most recent or most comprehensive publication was retained (eg, the latest published study [35] was included, while the earlier one [36] was excluded), and (3) full-text articles not in English or Chinese language.

    Stage 4: Charting the Data

    Decisions regarding the information to be recorded from the primary studies were made through discussions within the research group. Subsequently, a structured chart was developed to collate, summarize, and share the extracted data. A descriptive-analytical narrative approach was used to extract and chart the data from the selected articles [32,37]. Three researchers (XD, BY, and ZZ) independently extracted the data and performed coding, with the other two authors (HN and JW) verifying accuracy. All discrepancies were resolved by consensus. The following details were documented for each included study to answer the research questions: (1) nationality and publication year (Multimedia Appendix 2); (2) target users; (3) function structures; (4) recommendation content; (5) recommendation method, recommendation technology, data of training set, and recommendation process; and (6) evaluation method, evaluation criteria, test set, or evaluation sample size.

    Stage 5: Collating, Summarizing, and Reporting the Results

    The scoping review methodology aimed to summarize the breadth and depth of the existing literature. At this stage, an overview of the characteristics of all included articles was collated, summarized, and reported. Initially, a basic numerical summary of the studies, including the extent, nature, and distribution of the articles, was presented. As this was a scoping review, the critical appraisal of the quality of the included studies was not conducted. However, efforts were made to map the diversity and variety of diet-related HRSs based on factors such as the characteristics of target users, function structure, recommendation content, and other factors. This process facilitated researchers in reaching conclusions about the key characteristics of research in this field and provided insights for future studies.


    Overview

    In total, 4492 published studies were identified in the searching process (Figure 1). EndNote X9 was used to exclude 350 duplicates, and 4142 studies were excluded based on a review of their titles and abstracts. The remaining 208 studies were searched for full text. Ultimately, 193 were excluded based on the exclusion criteria, and 15 studies [35,38-51] were included and analyzed.

    Figure 1. Flow diagram according to the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines.

    The Current State of Research on Diet-Related HRSs for Patients with Chronic Health Conditions

    The publication years and the countries of the included studies are shown in Multimedia Appendix 2. The studies were published between 2010 and 2024, and there has not been a noticeable increase in their publication over the past 5 years. The articles originated from 9 countries (based on the first author’s affiliations), with the top 3 being China (n=5, 33.33%) [39,40,43,44,49], India (n=2, 13.33%) [41,47], and Pakistan (n=2, 13.33%) [38,48].

    Target Users for Diet-Related HRSs for Patients with Chronic Health Conditions

    Among the 15 included studies [35,38-51], only 2 reported the age of the target users, which were 18‐80 years [50] and older than 65 years [39], respectively. The target users and patients’ chronic health conditions are shown in Table 1. Diet-related HRSs primarily target adults with chronic diseases. Among chronic diseases, diabetes and hypertension were the most commonly targeted by diet-related HRSs, with 9 systems (60%) including users with diabetes and 6 (40%) including users with hypertension.

    Table 1. The characteristics of target users for diet-related Health Recommender Systems.
    VariableStudies, n (%)References
    Target users
     Patients with a single disease6 (40)[38,40,41,44,46,51]
     Patients with complex diseases4 (26.67)[39,43,47,48]
     Both healthy people and patients5 (33.33)[35,42,45,49,50]
    Patients’ chronic health conditions
     Diabetes9 (60)[35,38,42,45-49,51]
     Hypertension6 (40)[35,40,45,47-49]
     Cancer3 (20)[41,42,44]
     Obesity3 (20)[42,47,50]
     Kidney disease3 (20)[35,47,48]
     High cholesterol2 (13.33)[47,49]
     Metabolic syndrome1 (6.67)[43]
    Osteoporosis1 (6.67)[42]
    Iron deficiency1 (6.67)[48]
     Cardiovascular diseases1 (6.67)[42]
     Chronic dental problems1 (6.67)[42]
     Unspecified geriatric diseases1 (6.67)[39]

    The Function Structures in Diet-Related HRSs for Patients with Chronic Health Conditions

    Among the 15 studies included [35,38-51], 9 (60%) [35,38-45] studies described function structures. The function structures described in these studies varied, but certain recurring components were consistently noted, which could be summarized into 4 major components: user information, food or diet recommendations, knowledge and decision support, and data management and additional functions. Detailed information is shown in Table 2.

    Table 2. The function structures in diet-related Health Recommender Systems.
    VariableReferences
    User information
    Basic user information
     Personal/user profile[35,38,39]
     User information[40]
     History[35,41,42]
    Personal health information
     Physical activity[38]
     Health management report[43]
     Diseases[44]
     Symptoms[44]
    Diagnoses[41]
    Food or diet recommendations
    Food filter and security[35]
    Food recommendations or suggestions[38,45]
    Weekly meal plans[42]
    Diet guides[39,40]
    Knowledge and decision support
    Chronic kidney disease calculator[35]
    Food[38]
    Nutrient search engines[45]
    News and related sites[45]
    Ingredients[44]
    Nutritional expert knowledge[39]
    Clinical practice and nutrition guidelines[39]
    Knowledge base[39]
    Diet charts[41]
    User ratings[42]
    Data management and additional functions
    Data entry[38]
    Data management[40]
    Reminders[35]
    Real-time interaction[43]
    Settings[40]
    Changing details[41]

    The Types of Recommendation Content Provided by Diet-Related HRSs for Patients with Chronic Health Conditions

    The recommended content was divided into 5 categories. Detailed information is shown in Table 3.

    Table 3. The types of recommendation content provided by the diet-related Health Recommender Systems.
    Recommended contentStudies, n (%)References
    Food6 (40)[35,41,46-49]
    Recipe4 (26.67)[38,42,44,45]
    Diet plan or meal plan3 (20)[40,43,50]
    Both recipe and food1 (6.67)[51]
    Meal1 (6.67)[39]

    The Implementation of Recommendation Features in Diet-Related HRSs for Patients with Chronic Health Conditions

    Table 4 presents detailed information on the implementation of recommendation features in the reviewed diet-related HRSs. Recommendation methods were inductively classified into 3 categories: constraint-based, preference-based, and hybrid. In this review, constraint-based refers to recommendations based on the patient’s condition-related dietary restrictions, while preference-based refers to recommendations based on the patient’s dietary preferences. Hybrid refers to methods that incorporate both constraint-based and preference-based approaches. Among the 15 included studies [35,38-51], 6 (40%) used constraint-based methods [41,43,46,47,49,51], 5 (33.33%) applied preference-based methods [39,40,44,45,50], and 4 (26.67%) adopted hybrid methods [35,38,42,48].

    Table 4. The implementation of recommendation features in diet-related Health Recommender Systems.
    Author [reference], publication yearRecommendation methodRecommendation technologyData of the training setRecommendation process
    Phanich et al [46], 2010Constraint-basedHybrid
    recommendation    		Data were selected from the nutrition division, Ministry of Public Health, to form the training dataset (n=290a)
    • The dataset was grouped by the system and categorized according to food characteristics and nutrition for diabetes (normal food, limited food, and avoidable food).
    • Features were extracted by nutrient ranking.
    • Food clustering was analyzed.
    • Relevant food items were ranked based on the minimum distance, extracted, and recommended in ascending order from the ranking.
    Arwan et al [51], 2013Constraint-basedHybrid recommendationData were selected from some references of foods and enriched with the information from nutrition experts to form the training dataset (n=NRb).
    • The food ontology and calorie food ontology were developed.
    • The rule for classifying or grouping data categories within the ontology was developed.
    • The food menu search feature was built.
    • An experiment was conducted to test whether the system could recommend correctly.
    Faiz et al [38], 2014Preference-based and constraint-basedHybrid recommendationData were selected from standard and well-known resources such as the US Department of Agriculture and MyFitnessPal to form the training dataset (n=NRb).
    • The domain ontologies (personal health profile, food, and diseases) were built.
    • The ontologies were integrated and rule terms were defined.
    • The diet was recommended to the user at the predefined time.
    Ting et al [45], 2014Preference-basedHybrid recommendationData were selected from the Food Composition Database and Japan Preventive Association of Lifestyle-related Disease to form the training dataset (n=NRb).
    • A query with the user data was sent to the system.
    • Recipes were obtained from the database through a search.
    • Recipes that did not suit the current health status or match the user’s preferences were filtered out.
    • Five recipes were recommended from the filtered set.
    Chen et al [49], 2015Constraint-basedHybrid recommendationData were collected from the Taiwan Area Food Nutrition Database website published by the US Food and Drug Administration to form the training dataset (n=NRb).
    • The system collected personal information and classified the user’s nutrients.
    • The patient’s dietary records were imported into the nutrition expert knowledge system.
    • The personal information was imported into the personal disease ontology.
    • The nutrient data were analyzed by the expert knowledge system.
    • Suitable foods for the user were inferred.
    Tseng et al [43], 2015Constraint-basedHybrid recommendationc
    • The patient’s vital signs were collected and transmitted.
    • The risk was evaluated and reported.
    • A diet plan was generated and recommended to the patient.
    Elsweiler et al [50], 2015Preference-basedHybrid recommendationData were selected from a self-created food portal website, including users (n=148d) and recipes (n=957a) to form the training dataset.
    • The user’s nutritional requirements were established.
    • Recipe ratings were estimated based on each profile.
    • Recipes were combined.
    • Recipes were established if the combination met the requirements.
    Rehman et al [48], 2017Preference-based and constraint-basedHybrid recommendationData were selected from the official website of the Composition of Foods Integrated Dataset (CoFID) to form the training dataset (n=3400a).
    • A cloud-based food recommender system, named Diet-Right, was developed based on users’ pathological reports.
    • The ant colony algorithm was used to generate an optimal food list.
    • Suitable foods were recommended according to the values of pathological reports.
    Agapito et al [35], 2018Preference-based and constraint-basedHybrid recommendationc
    • The user profile was created by giving specific questions about clinical parameters.
    • All changes made by the user were saved, allowing the data to be used for monitoring the user’s health status.
    • After the user was profiled, typical foods that could be consumed by the user were recommended.
    Rathi et al [41], 2019Constraint-basedHybrid recommendationData were selected from the UC Irvine Machine Learning Repository (including the Liver Patient Dataset, Heart Disease Dataset, Diabetes Dataset, Breast Cancer Dataset, and Thyroid Dataset).
    • The dataset was collected and preprocessed from different sources.
    • The system was built to detect diseases and recommend diets accordingly.
    Manoharan et al [47], 2020Constraint-basedHybrid recommendationData were collected from 50 patients through the internet and hospitals to form the training dataset (n=50d).
    • Data were collected from the internet and hospitals.
    • Features were sorted, preprocessed, and encoded, and the food data were segregated based on similarities.
    • Food was recommended.
    • The system was trained, tested, and cross-validated.
    Qi et al [40], 2021Preference-basedHybrid recommendationData were selected from hospital meal history records and split into training and testing sets in a 7:3 ratio (n=718a).
    • A MySQL database was used to implement data dictionary management.
    • The rule extraction module was implemented with the knowledge base management system.
    • A meal plan was generated and recommended.
    Tang et al [44],
    2023    		Preference-basedKnowledge graphData were crawled from recipe websites and manually extracted from textbooks to form the training dataset (n=NRb).
    • The embedded representation of items was enhanced through message-passing and update functions on node features.
    • The influence of time on users’ taste preferences was considered.
    • Long Short-Term Memory (LSTM) networks were introduced to dynamically adjust users’ personal taste preferences.
    Zioutos et al [42],
    2024    		Preference-based and constraint-basedHybrid recommendationData were selected from a large real-world dataset of recipes to form the training dataset (n=2,774,676a).
    • The user’s health history was analyzed.
    • Similar users were identified.
    • Personalized recipe recommendations were provided.
    • Dynamically adaptable adjustments were made.
    Xu et al [39], 2024Preference-basedKnowledge graphData were selected from a community survey (n=96d) and a website of Chinese cuisine recipes and eating history (n=180a) to form the training dataset.
    • The FoodKG was constructed.
    • User profiles related to older adults’ dietary behaviors were built.
    • Personalized meal recommendation algorithms were developed, including candidate dish generation and combo meal recommendations.

    aThe sample size of subjects including a recipe, food, and diet plan or meal plan.

    bNR: not reported.

    cNot available.

    dThe sample size of the population.

    While the recommendation technologies were coded according to terms reported in the studies. The recommendation technology included: KG (n=2, 13.33%) [39,44] and HyR (n=13, 86.67%) [35,38,40-43,45-51].

    For the data of the training set, 13 studies (86.67%) [38-42,44-51] explicitly mentioned the data sources of the training set, while the other 2 studies (13.33%) [35,43] did not specify this information. The data sources used in the reviewed studies varied widely and can be categorized into 4 main types: authoritative government and institutional databases (n=5, 33.33%) [38,45,46,48,49], academic databases and publicly available datasets (n=2, 13.33%) [39,41], expert and hospital data (n=3, 20%) [40,47,51], and recipe and user-generated data (n=3, 20%) [42,44,50].

    The recommendation process followed a structured workflow, integrating advanced technologies to generate more accurate, adaptive, and context-aware dietary recommendations. The structured workflow included user profiling, integration of structured knowledge (such as food databases or ontologies), personalized filtering and matching based on health conditions and preferences, and ranking of suitable options for final recommendation. While this core process was consistent, 6 systems incorporated advanced technologies to enable more accurate, adaptable, and context-aware dietary recommendations, such as ontology-based reasoning [51], optimization algorithms (eg, ant colony [48]), dynamic modeling using Long Short-Term Memory networks [44], expert rule systems [39,49], and the use of KGs such as FoodKG [39].

    The Evaluation of Diet-Related HRSs for Patients with Chronic Health Conditions

    Among the 15 included studies [35,38-51], 12 studies (80%) [35,39-44,46-49,51] evaluated the diet-related HRSs, while the remaining 3 studies (20%) [38,45,50] did not conduct an evaluation. Table 5 presents detailed information on the evaluation criteria, evaluation method, and test set or evaluation sample size of the 12 studies [35,39-44,46-49,51].

    Table 5. The evaluation of diet-related Health Recommender Systems (n=12).
    Author [reference], publication yearEvaluation criteriaEvaluation methodTest set or evaluation sample size
    Phanich et al [46], 2010Acceptance, usability, and accuracyOnlineNutritionists (n=NRa)
    Arwan et al [51], 2013AccuracyOfflineOntology patient instances (n=30b)
    Chen et al [49], 2015AccuracyOnlineOne older adult from a silver-haired home and dietitians (n=NRa)
    Tseng et al [43], 2015FeasibilityOnlinePatients (n=NRa)
    Rehman et al [48], 2017AccuracyOfflineSame as the training set
    Agapito et al [35], 2018Accuracy and usabilityOnlinePatients with CKDc (n=20b); healthy people (n=20b)
    Rathi et al [41], 2019AccuracyOfflineSame as the training set. The dataset was split into training:testing 75:25 (n=9326d)
    Manoharan et al [47], 2020AccuracyOfflineSame as the training set
    Qi et al [40], 2021Efficiency and satisfactionOnlinePatients (n=37b) and nutritionists (n=3b)
    Tang et al [44], 2023AccuracyOfflineSame as the training set
    Zioutos et al [42], 2024Accuracy and usabilityOnline40 existing users of the food.com website: patients (n=20b) and healthy people (n=20b)
    Xu et al [39], 2024EffectivenessOnlineCommunity-dwelling older adults (n=96b): tracked group (n=34b) and an untracked group (n=62b); A total of 91 participants (94.79%) were diagnosed with chronic conditions

    aNR: not reported.

    bThe sample size of the population.

    cCKD: chronic kidney disease.

    dThe sample size of subjects including a recipe, food, and diet plan or meal plan.

    The evaluation criteria were extracted directly from the included studies, including: accuracy (n=9) [35,41,42,44,46-49,51] refers to the extent to which the system’s predictions of patients’ preferences or nutritional needs match their actual dietary preferences or intake; usability (n=3) [35,42,46] refers to the ease with which patients can, with little or no assistance, successfully operate the system to receive recommendations, navigate, and interact with its interface; acceptance (n=1) [46] refers to the degree to which patients are willing to receive and use the dietary recommendations provided by the system; satisfaction (n=1) [40] refers to patients’ subjective sense of contentment or evaluation of the overall usefulness and experience of the recommendations, measured through participants’ comprehensive comparison of system-generated meal plans with manually designed ones; efficiency (n=1) [40] refers to the amount of time, steps, or cognitive effort required for patients to obtain appropriate dietary recommendations from the system; feasibility (n=1) [43] refers to the practicality of deploying the recommendation system in real-life settings; and effectiveness (n=1) [39] refers to the actual positive impact of the system in real-life contexts on patients’ dietary behavior changes or health outcomes. Four studies [35,40,42,46] included more than one evaluation criterion.

    The evaluation methods included: online evaluation (n=7) [35,39,40,42,43,46,49] and offline evaluation (n=5) [41,44,47,48,51]. Among the 7 studies [35,38,42,44,45,48,51] that used online evaluation, 6 studies [35,39,40,42,43,49] evaluated the diet-related HRSs with target users of patients, while 3 studies evaluated the HRSs that relied on experts, such as nutritionists [40,46] and dietitians [49]; their main roles were to validate the recommendation results. Four of the 5 offline evaluation studies [39,40,43,46,47] used the same dataset for training and evaluation [41,44,47,48].


    Principal Findings

    This scoping review revealed that diet-related HRSs for individuals with chronic conditions were still in their early stages, with limited patient-specific designs and significant room for improvement. The review highlighted substantial gaps in target users, system functions, recommendation content, recommendation feature implementation, and evaluation approaches, which need to be addressed to support the development of more effective and patient-centered diet-related HRSs.

    Comparison with Prior Work

    Target Users of Diet-Related HRSs

    The target users of diet-related HRSs were mainly patients with single or complex chronic health conditions. They not only need dietary recommendations tailored to their preferences [39,41,42,44,48,50], but most importantly, their health conditions [38,40,45,46,51], highlighting the need for more disease-specific solutions. Age groups are another factor that needs to be considered, for example, older adults often face challenges such as limited mobility, cognitive decline, and changes in appetite or food preferences [40,42], while sick children and their caregivers face unique dietary needs due to treatment-related restrictions and appetite loss [52,53]. Therefore, balancing disease-related requirements with personal needs is fundamental to developing high-quality diet-related HRS. It is also essential to support caregivers in preparing meals that are nutritionally appropriate and medically compliant.

    Function Structures of Diet-Related HRSs

    The user information component enables diet-related HRSs to collect basic demographic and health data, which supports the generation of tailored dietary recommendations [35,38-40]. By incorporating dynamic inputs such as food tracking and activity logs, the system can further provide personalized, context-sensitive advice with timely feedback and adjustments based on patients’ health progress [43,54]. Knowledge and decision support functions served as a critical layer in enhancing the intelligence and reliability. For example, by integrating chronic kidney disease calculators [35], nutrient search engines [45], and expert knowledge bases [39], these systems move beyond simple food suggestions to provide evidence-based recommendations. This clarified how the nutritional rationale, which potentially enhances patients’ understanding and trust, long-term adherence, and sustainable dietary behavior change [44,45]. The accuracy and relevance of food or diet recommendations depend on the robustness of the algorithm used to process the data and the diversity of food or recipes options integrated into the system [55-57]. Data management and additional interactive functions have enhanced the usability and clinical relevance of diet-related HRSs and supported user engagement, empowering patients to actively and continuously manage their dietary self-care.

    Recommendation Content of Diet-Related HRSs

    Patients’ needs for the content of diet-related HRSs are multidimensional. Beyond simple food lists, an effective diet-related HRS must provide actionable guidance on cooking methods, ingredient combinations, and personalized meal plans [39,42-44,47,48,50]. Well-structured recipes emerge as a key feature, as they help users visualize meal preparation and improve understanding of the nutritional rationale behind recommendations [44]. Such transparency fosters engagement and adherence, particularly when supported by nutrition professionals [58,59]. Additionally, offering varied recipe options allows patients to personalize their meal plans according to their tastes, dietary restrictions, and the availability of ingredients [39]. This flexibility caters to users with complex health conditions and empowers them with a sense of control, which is vital for sustaining long-term dietary management [42].

    Implementation of Recommendation Features in Diet-Related HRSs
    Recommendation Methods

    In diet-related HRSs, hybrid approaches appear particularly valuable for balancing clinical appropriateness with individual preferences to promote long-term adherence. In addition, adaptability is an essential feature, allowing systems to respond to changing health conditions, behaviors, and user needs. As patients’ health status and preferences evolve, systems such as “SHARE” demonstrate the value of dynamic updates that allow users to refine their meal plans, making the system more user-centered and responsive [42]. However, a critical gap across the reviewed studies is the insufficient consideration of medication-food interactions. For patients with chronic conditions, clinically significant interactions such as warfarin-vitamin K [60], angiotensin-converting–enzyme inhibitors-potassium [61], or metformin-alcohol [62], carry substantial risks. Future diet-related HRSs should adopt hybrid approaches that integrate drug-nutrient knowledge and dynamic monitoring with preference learning, ensuring recommendations that are both personalized and clinically safe.

    Recommendation Technology

    Appropriate recommendation technology can transform users’ vague needs into clear ones and filter out irrelevant information [63]. HyR that combines CF, CB, and KB methods is particularly effective. These methods overcome traditional limitations such as cold start and data sparsity by integrating multiple information sources, including nutritional knowledge and disease-specific data [64]. Notably, KB and KG-driven algorithms were especially well-suited for diet-related HRSs. By incorporating expert knowledge and medical guidelines, they ensure scientific accuracy, clinical reliability, and alignment with patients’ dietary management goals, resulting in more comprehensive and robust systems [65].

    Data Sources

    The effectiveness of diet-related HRSs largely depends on the quality and appropriateness of data sources. Patient data mainly come from personal input, including medical records, treatment history, and sociodemographic information [35,38-45,47-49]. Incorporating dietary behavior data (eg, meal logs, food purchase records, and subjective reports) and clinical data (eg, diagnosis, treatment, and disease stage) helps ensure that dietary recommendations are both personalized and medically appropriate [66,67]. Although patient-specific data are essential for personalized recommendations [35,44], sensitive medical and behavioral data entail serious privacy, security, and ethical risks. Given patients’ fragile health status and dietary restrictions, dietary data from professional resources, such as the Nutrition Division of the Ministry of Public Health (MOPH) [46], the official website of the composition of foods integrated dataset (CoFID) [48], and the Japan Preventive Association of Lifestyle-related Disease (JPALD) [45], are vital for ensuring the accuracy of recommendations. In contrast, nonprofessional sources such as general cooking websites are not recommended in clinical contexts due to their limited reliability, particularly for patients with complex conditions.

    Implementation Process

    The Association for Computing Machinery has issued guidelines for designing and evaluating RSs [68]. However, no widely accepted standards have been established for implementing HRSs, especially diet-related HRSs. This gap highlights challenges arising from disease diversity, complex food preferences, and context-dependent factors that are difficult to acquire or simulate [28]. The reviewed systems generally followed a similar workflow, involving user profiling, structured knowledge integration, personalized filtering, and ranking, reflecting a growing understanding of how to align dietary recommendations with individual health needs and preferences. The integration of advanced recommendation technologies, such as ontology-based reasoning [51], optimization algorithms (eg, ant colony methods [48]), Long Short-Term Memory–based dynamic modeling [44], and KGs [39], has advanced more intelligent and context-aware systems. However, the adoption of these technologies remains limited, and few studies have systematically evaluated their impact on recommendation quality or patient outcomes.

    Evaluation of Diet-Related HRSs

    Evaluation Criteria

    In diet-related HRSs, accuracy has been the primary evaluation criterion, typically evaluated by prediction score accuracy, prediction score correlation, classification accuracy, and sorting accuracy [69]. However, the rationality of the recommendations has received limited attention. None of the 15 reviewed studies [35,38-51] evaluated the scientific soundness of food or recipe recommendations. While health care providers were commonly involved in evaluating the recommendation results, official institutional input on content was rare, revealing a major gap in ensuring the credibility and reliability of recommendations.

    Beyond accuracy and content rationality, the effectiveness of diet-related HRSs is closely tied to their ability to promote healthy eating behaviors. The key goal of the diet-related HRSs is to empower users to make informed dietary choices and motivate healthier behaviors [70]. Existing evaluations of behavior change have primarily examined improvements in diet quality and diversity, measured by the China Elderly Dietary Guidelines Index and the dietary diversity score [50]. Although user engagement and personalized feedback were recognized as essential for sustaining behavior change, few studies evaluated long-term effects on patients’ dietary behaviors.

    Moreover, clinical trials in real-world health care settings remain lacking; even the study [39] involving patients was an observational cohort study rather than a clinical trial, limiting statistical power and generalizability. Additionally, no studies examined the cost-effectiveness of implementing diet-related HRSs in health care settings, which is crucial for adoption in resource-constrained healthcare systems.

    Evaluation Methods and Process

    The evaluation of diet-related HRSs can be carried out using various methods, each with its advantages and limitations. Online evaluations, which assess system performance through real-time user feedback or surveys, provide valuable insights into user interactions but often involve higher costs [22]. Offline evaluations in controlled settings are more feasible but have limited external validity due to their inability to reflect real-world usage [22,71]. Emerging approaches such as online A or B testing enable rapid, cost-effective comparisons of different system versions, helping predict broader performance even with small samples [72,73].

    Diet-related HRS evaluations generally follow a staged approach from development to postdeployment. During development, stakeholder involvement in usability evaluation is critical to ensure user-centered design [74]. After development, accurate assessments verify that recommendations are reliable and relevant to target users [35,41,42,44,46-49,51]. Postdevelopment, gathering user feedback on effectiveness and satisfaction is essential for refining the system and improving its responsiveness to user needs [35,39,40,42,43,46]. These stages form a comprehensive evaluation process ensuring the reliability and usability of diet-related HRSs.

    Although several reviews have examined HRSs, few have focused specifically on diet-related HRSs. One scoping review of 36 studies identified only 8 diet-focused HRSs [75]. A systematic review of 73 studies identified 26 nutrition-related systems, most of which targeted populations without strict medical dietary requirements, thereby revealing the lack of disease-specific syntheses [22]. Existing diet-related HRS reviews have primarily addressed technical aspects, such as semantic interoperability [76], explainable artificial intelligence [77], and data-driven personalization methods [78]. They offer useful technical insights but rarely address disease-specific dietary needs or the related clinical and safety challenges. In contrast, our review focuses on diet-related HRSs for patients with chronic conditions. It highlights key requirements such as clinical data integration, dynamic health monitoring, tailored recipe-level recommendations, and persistent gaps in evaluating behavior change and clinical outcomes. These disease-focused insights extend prior work and inform the development of more personalized and clinically reliable diet-related HRSs.

    Future Directions

    Future research should prioritize developing diet-related HRSs based on a user-centered design framework. These systems must be tailored to patients’ specific needs with a deep understanding of their cognitive abilities, digital literacy, cultural dietary preferences, and daily routines. Diet-related HRSs need to address clinical challenges through contextually relevant functional designs, customized for different patient groups, from older adults with multimorbidity to pediatric patients requiring caregiver-mediated support. Practical usability features, such as adaptive reminders, contextualized recipe guidance, and dynamic feedback loops, are essential for real-world effectiveness.

    To support patients’ sustained dietary behavior change, recommendations should move beyond static food lists toward evidence-based, actionable guidance using practical tools such as portion guides, ingredient lists, and meal preparation videos [79]. Future systems should adopt hybrid, adaptive recommendation mechanisms and integrate with electronic health records (EHRs) and mobile apps to enhance personalization, interpretability, clinical relevance, and engagement, which is essential for sustaining long-term adherence to dietary changes. Additionally, incorporating behavior change theories, such as Social Cognitive Theory [80], Theory of Planned Behavior [81], and the Fogg Behavior Model [82], can strengthen the dietary intervention design. Gamification elements informed by these theories, such as rewards and rankings, may further motivate users and increase adherence [83].

    When managing sensitive health data, especially when integrating with EHRs and personal medical records, the systems must implement robust data governance, including secure storage, encryption, role-based access, and transparent consent. Compliance with regulations such as the US Health Insurance Portability and Accountability Act (HIPAA) [84], the European Union’s General Data Protection Regulation (GDPR) [85], and national standards are essential to safeguard patient privacy and foster user trust. Finally, standardized evaluation methods and robust frameworks, combining clinical trials, behavior change evaluation, and usability evaluation, are essential to verify effectiveness, accuracy, and long-term impact in real-world settings, while ensuring cost-effectiveness and compliance (eg, US Food and Drug Administration approval and European Conformity marking) for safe and scalable healthcare implementation.

    Implication for Clinical Practice

    For clinicians and dietitians, diet-related HRSs can serve as supportive tools to deliver personalized, evidence-based, and adaptive dietary guidance aligned with patients’ medical conditions, treatment regimens, cultural preferences, and daily routines. By incorporating medication-food interaction checks and actionable educational content, these systems can enhance patient safety, dietary adherence, and long-term health management. Future diet-related HRSs could integrate seamlessly into clinical workflows and demonstrate measurable health outcomes. Embedding diet-related HRSs within EHRs would ensure that dietary recommendations are consistent with medications, lab results, and care plans. By linking dietary adherence to physiological indicators such as hemoglobin A1c, blood pressure, or lipid levels, systems can enable real-time feedback and timely clinical intervention. Beyond accuracy, future evaluations should predefine clinical end points (eg, hemoglobin A1c reduction or blood pressure control) and validate effectiveness through randomized controlled trials and real-world studies.

    Limitations

    This study has several limitations. First, only studies published from January 2010 to October 2024 were included, which may not reflect recent developments. Second, only English and Chinese literature were reviewed, excluding studies in other languages. Third, the focus was primarily on chronic health conditions, with limited exploration of diet-related HRSs for acute conditions or general wellness, suggesting a need for broader research in future studies. In addition, the included studies themselves demonstrated certain methodological limitations, such as small sample sizes, reliance on offline testing, and limited evaluation of actual behavior change. These issues reflect not only the limitations of this review but also highlight gaps in the existing research that warrant more rigorous clinical evaluation.

    Conclusions

    Diet-related HRSs can offer personalized dietary recommendations for patients with chronic conditions. The analysis reveals significant gaps, demanding that future systems be grounded in user-centered design to meet patient-specific needs. These systems must recommend more practical and actionable dietary guidance. The adoption of hybrid recommendation techniques can enhance the precision and clinical relevance of dietary recommendations. Establishing standardized evaluation metrics and conducting real-world studies with long-term follow-up will be essential. This will verify the system’s ability to positively change dietary behaviors and improve clinical outcomes. Addressing these issues will transform diet-related HRSs into trustworthy and impactful tools for managing chronic diseases and delivering patient-centered care.

    Acknowledgments

    We would like to thank Liping Fu for her assistance and guidance in developing the search strategy.

    Generative artificial intelligence and artificial intelligence–assisted technologies in the writing process: during the preparation of this work, the authors used ChatGPT 4.0 to improve the readability and language of the manuscript. After using this tool, the authors reviewed and edited the content as needed and take full responsibility for the content of the published article.

    Funding

    This study was supported by the National Natural Science Foundation of China (grant number 72374204) and Soft Science Research Project of Shanghai (25692108400).

    Authors' Contributions

    Conceptualization: XD, JW

    Data curation: XD, BY, HN, TJ, JW

    Formal analysis: XD, BY, ZZ, JW

    Project administration: XD, JW

    Supervision: AP, CY, JW

    Visualization: XD

    Writing – original draft: XD, BY, ZZ, JW

    Writing – review & editing: XD, BY, AP, JW

    Conflicts of Interest

    None declared.

    Multimedia Appendix 1

    Search strategy.

    PDF File, 850 KB

    Multimedia Appendix 2

    The publication years and countries of the included studies.

    PNG File, 82 KB

    Checklist 1

    PRISMA-ScR Checklist.

    PDF File, 114 KB
    1. Murray CJL, Aravkin AY, Zheng P, et al. Global burden of 87 risk factors in 204 countries and territories, 1990–2019: a systematic analysis for the Global Burden of Disease Study 2019. Lancet. Oct 2020;396(10258):1223-1249. [CrossRef]
    2. The Global Nutrition Report. URL: https://globalnutritionreport.org/ [Accessed 2025-12-31]
    3. Ong KL, Stafford LK, McLaughlin SA, et al. Global, regional, and national burden of diabetes from 1990 to 2021, with projections of prevalence to 2050: a systematic analysis for the Global Burden of Disease Study 2021. Lancet. Jul 2023;402(10397):203-234. [CrossRef]
    4. Magkos F, Hjorth MF, Astrup A. Diet and exercise in the prevention and treatment of type 2 diabetes mellitus. Nat Rev Endocrinol. Oct 2020;16(10):545-555. [CrossRef] [Medline]
    5. Filippou CD, Tsioufis CP, Thomopoulos CG, et al. Dietary Approaches to Stop Hypertension (DASH) diet and blood pressure reduction in adults with and without hypertension: a systematic review and meta-analysis of randomized controlled trials. Adv Nutr. Sep 1, 2020;11(5):1150-1160. [CrossRef] [Medline]
    6. Zhuang P, Wang F, Yao J, et al. Unhealthy plant-based diet is associated with a higher cardiovascular disease risk in patients with prediabetes and diabetes: a large-scale population-based study. BMC Med. Oct 23, 2024;22(1):485. [CrossRef] [Medline]
    7. Lockwood G, Davey L, McFarlane C, Gray NA, Wright HH. Factors influencing meal provision and dietary support behaviour of caregivers of people with chronic kidney disease: a cross-sectional study. Nutrients. Oct 14, 2024;16(20):3479. [CrossRef] [Medline]
    8. Xiong H, Zhang X, Zeng H, Xie S, Yi S. Experience of diet in patients with inflammatory bowel disease: a thematic synthesis of qualitative studies. J Clin Nurs. Aug 2024;33(8):3283-3293. [CrossRef] [Medline]
    9. Scientific research report on dietary guidelines for Chinese residents [Website in Chinese]. National Institute for Nutrition and Health, Chinese Center for Disease Control and Prevention; 2021. URL: https://www.chinanutri.cn/yyjkzxpt/yyjkkpzx/yytsg/zgjm/202103/t20210311_224598.html [Accessed 2025-12-31]
    10. Dahl C, Crichton M, Jenkins J, et al. Evidence for dietary fibre modification in the recovery and prevention of reoccurrence of acute, uncomplicated diverticulitis: a systematic literature review. Nutrients. Jan 27, 2018;10(2):137. [CrossRef] [Medline]
    11. Collins N, Belkaid Y. Control of immunity via nutritional interventions. Immunity. Feb 8, 2022;55(2):210-223. [CrossRef] [Medline]
    12. Dietary Guidelines for Americans. US Department of Health and Human Services and US Department of Agriculture; 2015. URL: https://odphp.health.gov/sites/default/files/2019-09/2015-2020_Dietary_Guidelines.pdf [Accessed 2025-11-05]
    13. Flaskerud JH. Mood and food. Issues Ment Health Nurs. Apr 2015;36(4):307-310. [CrossRef] [Medline]
    14. Notice on the issuance of dietary guidelines for the prevention and management of hyperuricemia and gout in adults (2024 edition) and three other dietary guidelines [Report in Chinese]. National Health Commission of the People’s Republic of China; 2024. URL: https:/​/www.​nhc.gov.cn/​wjw/​c100378/​202402/​afd5dda4bd6745fda10aad8d43a16369/​files/​1732845129551_37712.​pdf [Accessed 2025-12-31]
    15. Rines J, Daley K, Loo S, et al. A patient-led, peer-to-peer qualitative study on the psychosocial relationship between young adults with inflammatory bowel disease and food. Health Expect. Aug 2022;25(4):1486-1497. [CrossRef] [Medline]
    16. Singh PK, Pramanik PKD, Dey AK, Choudhury P. Recommender systems: an overview, research trends, and future directions. Int J Bus Syst Res. 2021;15(1):14. [CrossRef]
    17. Su X, Khoshgoftaar TM. A survey of collaborative filtering techniques. Adv Artif Intell. Oct 27, 2009;2009(1):1-19. [CrossRef] [Medline]
    18. Lops P, de Gemmis M, Semeraro G. Content-based recommender systems: state of the art and trends. In: Recommender Systems Handbook. Springer; 2011:73-105. [CrossRef]
    19. Burke R. Knowledge-based recommender systems. Encycl Libr Inf Syst. 2000;69(Supplement 32). URL: https://api.semanticscholar.org/CorpusID:15088589 [Accessed 2025-12-31]
    20. Hou S, Wei D. Research on knowledge graph-based recommender systems. Presented at: 2023 3rd International Symposium on Computer Technology and Information Science (ISCTIS); Jul 7-9, 2023. [CrossRef]
    21. Muñoz EG, Parraga-Alava J, Meza J, Proaño Morales JJ, Ventura S. Housing fuzzy recommender system: a systematic literature review. Heliyon. Mar 15, 2024;10(5):e26444. [CrossRef] [Medline]
    22. De Croon R, Van Houdt L, Htun NN, Štiglic G, Vanden Abeele V, Verbert K. Health Recommender Systems: systematic review. J Med Internet Res. Jun 29, 2021;23(6):e18035. [CrossRef] [Medline]
    23. Siriaraya P, Suzuki K, Nakajima S. Utilizing collaborative filtering to recommend opportunities for positive affect in daily life. HealthRecSys@ RecSys. 2019. URL: https://api.semanticscholar.org/CorpusID:202890918 [Accessed 2025-12-31]
    24. Pasta A, Petersen MK, Jensen KJ, Larsen JE. Rethinking hearing aids as recommender systems. CEUR Workshop Proc. 2019:11-17. URL: https:/​/backend.​orbit.dtu.dk/​ws/​portalfiles/​portal/​200371078/​Rethinking_Hearing_Aids_as_Recommender_Systems.​pdf [Accessed 2025-12-31]
    25. Sanchez Bocanegra CL, Sevillano Ramos JL, Rizo C, Civit A, Fernandez-Luque L. HealthRecSys: a semantic content-based recommender system to complement health videos. BMC Med Inform Decis Mak. May 15, 2017;17(1):63. [CrossRef] [Medline]
    26. Agu E, Claypool M. Cypress: a cyber-physical recommender system to discover smartphone exergame enjoyment. Presented at: Proceedings of the ACM workshop on engendering health with recommender systems; Sep 15-16, 2016. URL: https://web.cs.wpi.edu/~claypool/papers/cypress-recsys/paper.pdf [Accessed 2025-12-31]
    27. Chavan P, Thoms B, Isaacs J. A recommender system for healthy food choices: building a hybrid model for recipe recommendations using big data sets. In: Chavan P, Thoms B, Isaacs J, editors. Presented at: Hawaii International Conference on System Sciences; Jan 5-8, 2021. [CrossRef]
    28. Mahajan P, Kaur PD. A systematic literature review of food recommender systems. SN Comput Sci. 2024;5(1):1-26. [CrossRef]
    29. Trattner C, Elsweiler D. Food recommender systems: important contributions, challenges and future research directions. arXiv. Preprint posted online on Nov 7, 2017. [CrossRef]
    30. Islam T, Joyita AR, Alam M, Mehedi Hassan M, Hassan M, Gravina R. Human-behavior-based personalized meal recommendation and menu planning social system. IEEE Trans Comput Soc Syst. 2022;10(4):2099-2110. [CrossRef]
    31. Vandeputte J, Herold P, Kuslii M, et al. Principles and validations of an artificial intelligence-based recommender system suggesting acceptable food changes. J Nutr. Feb 2023;153(2):598-604. [CrossRef] [Medline]
    32. Arksey H, O’Malley L. Scoping studies: towards a methodological framework. Int J Soc Res Methodol. Feb 2005;8(1):19-32. [CrossRef]
    33. Tricco AC, Lillie E, Zarin W, et al. PRISMA Extension for Scoping Reviews (PRISMA-ScR): checklist and explanation. Ann Intern Med. Oct 2, 2018;169(7):467-473. [CrossRef] [Medline]
    34. Song HS, Kim YA. A dog food recommendation system based on nutrient suitability. Expert Systems. Mar 2021;38(2). [CrossRef]
    35. Agapito G, Simeoni M, Calabrese B, et al. DIETOS: a dietary recommender system for chronic diseases monitoring and management. Comput Methods Programs Biomed. Jan 2018;153:93-104. [CrossRef] [Medline]
    36. Agapito G, Calabrese B, Guzzi PH, et al. DIETOS: a recommender system for adaptive diet monitoring and personalized food suggestion. Presented at: 2016 IEEE 12th International Conference on Wireless and Mobile Computing, Networking and Communications (WiMob); Oct 17-19, 2016. [CrossRef]
    37. Wang J, Yuan C. Evidence-based scoping reviews: an introduction to the methodology. J Nurs Sci. 2017;32(8):103-105. URL: https://tinyurl.com/3pypvaac [Accessed 2026-01-08] [CrossRef]
    38. Faiz I, Mukhtar H, Khan S. An integrated approach of diet and exercise recommendations for diabetes patients. Presented at: 2014 IEEE 16th International Conference on e-Health Networking, Applications and Services (Healthcom 2014); Oct 15-18, 2014. [CrossRef]
    39. Xu Z, Gu Y, Xu X, et al. Developing a personalized meal recommendation system for Chinese older adults: observational cohort study. JMIR Form Res. May 30, 2024;8:e52170. [CrossRef] [Medline]
    40. Qi M, Chen W, Li D, Yang F. Design of a knowledge-based nutritional meal recommendation system for patients. China Med Equip. 2021;18(1). [CrossRef]
    41. Rathi M, Pareek V. Mobile based healthcare tool an integrated disease prediction & recommendation system. Int J Knowl Syst Sci. 2019;10(1):38-62. [CrossRef]
    42. Zioutos K, Kondylakis H, Stefanidis K. Healthy personalized recipe recommendations for weekly meal planning. Computers. 2024;13(1):1. [CrossRef]
    43. Tseng JCC, Lin BH, Lin YF, et al. An interactive healthcare system with personalized diet and exercise guideline recommendation. Presented at: 2015 Conference on Technologies and Applications of Artificial Intelligence (TAAI); Nov 20-22, 2015. [CrossRef]
    44. Tang J, Huang B, Xie M. Anticancer recipe recommendation based on cancer dietary knowledge graph. Eur J Cancer Care (Engl). Oct 18, 2023;2023:1-13. [CrossRef]
    45. Ting YH, Zhao Q, Chen RC. Dietary recommendation based on recipe ontology. Presented at: 2014 IEEE 6th International Conference on Awareness Science and Technology (iCAST); Oct 29-31, 2014. [CrossRef]
    46. Phanich M, Pholkul P, Phimoltares S. Food recommendation system using clustering analysis for diabetic patients. Presented at: 2010 International Conference on Information Science and Applications; Apr 21-23, 2010. [CrossRef]
    47. Manoharan D. Patient diet recommendation system using K clique and deep learning classifiers. J Artif Intell Capsule Netw. 2020;2(2):121-130. [CrossRef]
    48. Rehman F, Khalid O, Haq N, Khan AUR, Bilal K, Madani S. Diet-Right: a smart food recommendation system. KSII TIIS. 2017;11(6):2910-2925. [CrossRef]
    49. Chen RC, Ting YH, Chen JK, Lo YW. The nutrients of chronic diet recommended based on domain ontology and decision tree. Presented at: 2015 Conference on Technologies and Applications of Artificial Intelligence (TAAI); Dec 2-4, 2015. [CrossRef]
    50. Elsweiler D, Harvey M. Towards automatic meal plan recommendations for balanced nutrition. Presented at: RecSys ’15; Sep 16-20, 2015:313-316; Vienna, Austria. [CrossRef]
    51. Arwan A, Sidiq M, Priyambadha B, Kristianto H, Sarno R. Ontology and semantic matching diabetic food recommendations. Presented at: 2013 International Conference on Information Technology and Electrical Engineering (ICITEE); Oct 7-8, 2013. [CrossRef]
    52. Wang Y, Wang J, Yu S, Zhou F, Yuan C. Qualitative study on the needs of parents of children with newly diagnosed acute lymphoblastic leukemia. J Nurs PLA China. 2016;33(4):6-10. URL: https://tinyurl.com/36wzty6p [Accessed 2026-01-08]
    53. van den Brink M, Ter Hedde MM, van den Heuvel E, Tissing WJE, Havermans RC. The impact of changes in taste, smell, and eating behavior in children with cancer undergoing chemotherapy: a qualitative study. Front Nutr. 2022;9:984101. [CrossRef] [Medline]
    54. Zenun Franco R, Fallaize R, Weech M, Hwang F, Lovegrove JA. Effectiveness of web-based personalized nutrition advice for adults using the eNutri web app: evidence from the EatWellUK randomized controlled trial. J Med Internet Res. Apr 25, 2022;24(4):e29088. [CrossRef] [Medline]
    55. Celis-Morales C, Livingstone KM, Marsaux CF, et al. Effect of personalized nutrition on health-related behaviour change: evidence from the Food4Me European randomized controlled trial. Int J Epidemiol. Apr 1, 2017;46(2):578-588. [CrossRef] [Medline]
    56. Ordovas JM, Ferguson LR, Tai ES, Mathers JC. Personalised nutrition and health. BMJ. Jun 13, 2018;361:bmj.k2173. [CrossRef] [Medline]
    57. Melese A. Food and restaurant recommendation system using hybrid filtering mechanism. North Am Acad Res (NAAR). 2021;4(4):268-281. [CrossRef]
    58. Worthington A, Coffey T, Gillies K, Roy R, Braakhuis A. Exploring how researchers consider nutrition trial design and participant adherence: a theory-based analysis. Front Nutr. 2024;11:1457708. [CrossRef] [Medline]
    59. Mattei J, Alfonso C. Strategies for healthy eating promotion and behavioral change perceived as effective by nutrition professionals: a mixed-methods study. Front Nutr. 2020;7:114. [CrossRef] [Medline]
    60. Holbrook AM, Pereira JA, Labiris R, et al. Systematic overview of warfarin and its drug and food interactions. Arch Intern Med. May 23, 2005;165(10):1095-1106. [CrossRef] [Medline]
    61. Palmer BF. Managing hyperkalemia caused by inhibitors of the renin-angiotensin-aldosterone system. N Engl J Med. Aug 5, 2004;351(6):585-592. [CrossRef] [Medline]
    62. Bailey CJ, Turner RC. Metformin. N Engl J Med. Feb 29, 1996;334(9):574-579. [CrossRef] [Medline]
    63. Joy J, Pillai RVG. Review and classification of content recommenders in E-learning environment. J King Saud Univ, Comput Inf Sci. Oct 2022;34(9):7670-7685. [CrossRef]
    64. Ayemowa MO, Ibrahim R, Bena YA. A systematic review of the literature on deep learning approaches for cross-domain recommender systems. Decision Analytics Journal. Dec 2024;13:100518. [CrossRef]
    65. Abhari S. A systematic review of nutrition recommendation systems: with focus on technical aspects. J Biomed Phys Eng. Dec 2019;9(6). [CrossRef]
    66. Arakaki M, Li L, Kaneko T, et al. Personalized nutritional therapy based on blood data analysis for malaise patients. Nutrients. Oct 18, 2021;13(10):3641. [CrossRef] [Medline]
    67. Shim JS, Oh K, Kim HC. Dietary assessment methods in epidemiologic studies. Epidemiol Health. 2014;36:e2014009. [CrossRef] [Medline]
    68. Zangerle E, Bauer C. Evaluating recommender systems: survey and framework. ACM Comput Surv. Aug 31, 2023;55(8):1-38. [CrossRef]
    69. Zhu Y, Lyu L. Review of evaluation metrics for recommender systems. J Univ Electron Sci Technol China. 2012;41(2):163-175. [CrossRef]
    70. Wang J, Dong X, Jin T, Yuan C. Research progress and prospects of health recommendation systems. J Med Intell. 2024;45(1):70-76. URL: https://tinyurl.com/4zas9nm8 [Accessed 2026-01-08]
    71. Rossetti M, Stella F, Zanker M. Contrasting offline and online results when evaluating recommendation algorithms. Presented at: RecSys ’16; Sep 15-19, 2016. [CrossRef]
    72. Kohavi R, Longbotham R. Online controlled experiments and a/b testing. In: Sammut C, Webb GI, editors. Encyclopedia of Machine Learning and Data Mining. Springer; 2017:922-929. [CrossRef]
    73. Georgiev GZ. Statistical Methods in Online A/B Testing: Statistics for Data-Driven Business Decisions and Risk Management in e-Commerce: Georgi Z. Georgiev; 2019. ISBN: 1694079724
    74. Sun Y, Zhou J, Ji M, Pei L, Wang Z. Development and evaluation of health recommender systems: systematic scoping review and evidence mapping. J Med Internet Res. Jan 19, 2023;25:e38184. [CrossRef] [Medline]
    75. Ananthakrishnan A, Milne-Ives M, Cong C, et al. The evaluation of health recommender systems: a scoping review. Int J Med Inform. Mar 2025;195:105697. [CrossRef] [Medline]
    76. Xhani D, Sedrakyan G, Gavai A, Guizzardi R, van Hillegersberg J. The role and applications of semantic interoperability tools and eXplainable AI in the development of smart food systems: findings from a systematic literature review. Intell Syst Appl. Sep 2025;27:200547. [CrossRef]
    77. Kalu KA, Ataguba G, Onifade O, Orji F, Giweli N, Orji R. Application of artificial intelligence technologies as an intervention for promoting healthy eating and nutrition in older adults: a systematic literature review. Nutrients. Oct 14, 2025;17(20):3223. [CrossRef] [Medline]
    78. Tsolakidis D, Gymnopoulos LP, Dimitropoulos K. Artificial intelligence and machine learning technologies for personalized nutrition: a review. Informatics (MDPI). 2024;11(3):62. [CrossRef]
    79. Anderson HL, Moore JE, Millar BC. Comparison of innovative communication approaches in nutrition to promote and improve health literacy. Ulster Med J. May 2022;91(2):85-91. [Medline]
    80. Locke EA, Bandura A. Social foundations of thought and action: a social-cognitive view. Acad Manag Rev. Jan 1987;12(1):169. [CrossRef]
    81. Ajzen I. The theory of planned behavior. Organ Behav Hum Decis Process. Dec 1991;50(2):179-211. [CrossRef]
    82. Fogg BJ. Persuasive technology: using computers to change what we think and do. Ubiquity. 2002;2002. [CrossRef]
    83. Wu X, Xin X. The application of gamification design in persuading users’ behavior change [Article in Chinese]. Packag Eng. 2017;38(20):194-198. URL: https://d.wanfangdata.com.cn/periodical/bzgc201720037 [Accessed 2025-12-31]
    84. Cole LJ, Fleisher LD. Update on HIPAA privacy: are you ready? Genet Med. 2003;5(3):183-186. [CrossRef] [Medline]
    85. Voigt P, von dem Bussche A. The EU General Data Protection Regulation (GDPR): A Practical Guide. Springer Publishing Company, Incorporated; 2017. [CrossRef] ISBN: 3319579584

    CB: content-based
    CF: collaborative filtering
    CoFID: composition of foods integrated dataset
    EHR: electronic health record
    GDPR: General Data Protection Regulation
    HIPAA: Health Insurance Portability and Accountability Act
    HRS: Health Recommender System
    HyR: hybrid recommendation
    JPALD: Japan Preventive Association of Lifestyle-related Disease
    KB: knowledge-based
    KG: knowledge graph
    MOPH: Ministry of Public Health
    PRISMA: Preferred Reporting Items for Systematic Reviews and Meta-Analyses
    PRISMA-ScR: Preferred Reporting Items for Systematic Reviews and Meta-Analyses Extension for Scoping Reviews
    RS: Recommender System

    Edited by Naomi Cahill; submitted 19.May.2025; peer-reviewed by Abiye Berihun, Chukwudi Okolue, Timothy Ojo; accepted 01.Dec.2025; published 14.Jan.2026.

    Copyright

    © Xiaolan Dong, Bei Yun, Anni Pakarinen, Zhuting Zheng, Hao Niu, Tian Jin, Changrong Yuan, Jingting Wang. Originally published in the Journal of Medical Internet Research (https://www.jmir.org), 14.Jan.2026.

    This is an open-access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work, first published in the Journal of Medical Internet Research (ISSN 1438-8871), is properly cited. The complete bibliographic information, a link to the original publication on https://www.jmir.org/, as well as this copyright and license information must be included.