Assessing the quality of study design: hierarchies of evidence

Research designs offer different levels of confidence about the results of the research, and the idea of a hierarchy of evidence has been used widely. Hierarchies of evidence describing the efficacy of health interventions are often drawn as pyramids, showing weaker study designs at the bottom and stronger study designs at the top. At least 80 different hierarchies of evidence have been identified^{(Reference Blunt10)}, and most follow a similar order, focusing on the ability of the study design to test the efficacy of interventions in humans. ‘Expert opinion’ and ‘mechanistic’ research performed in vitro or in animal models (as opposed to mechanistic studies in human ‘randomised controlled trials’ (RCT)) are placed at the bottom, followed by ‘observations in individuals or small groups of humans’ (e.g. case reports, case series), followed by ‘observational studies’ in the middle (case–control (retrospective), cohort (prospective)), followed by ‘RCT’ and finally ‘systematic reviews and meta-analysis of RCT at the very top (Fig. 2(a)). For an intervention to be useful it must be both efficacious (i.e. able to produce the desired result under controlled, ideal circumstances) and effective (i.e. able to produce the desired result in the ‘real-world’ conditions while considering acceptability, adherence and feasibility)^{(Reference Singal, Higgins and Waljee11)}. The study designs required to assess efficacy and effectiveness are necessarily distinct, and therefore, a combination of study designs is typically required to thoroughly understand the implementation and impact of an intervention. Therefore, the ‘best’ method by which to acquire evidence depends on the research question⁽¹²⁾. Nevertheless, hierarchies of the most appropriate study designs remain part of the quality framework with adequately powered multi-centre trials and systematic reviews of any kind of study design considered to provide the most powerful evidence (Fig. 3)^{(Reference Evans13)}. Existing hierarchical schemes also do not refer to emerging or novel research methods, such as pragmatic trials, implementation science and real-world health data.

Fig. 2. Traditional and proposed alterations to hierarchies of evidence to support the efficacy of an intervention. (a) The traditional pyramid ranging from case reports and case series at the bottom and systematic reviews and meta-analyses at the top; (b) lines separating the study designs become wavy as a result of variations in study quality, and systematic reviews are separated from the pyramid; (c) lines separating the study designs become wavy as a result of variations in study quality, and systematic reviews are no longer at the top of the hierarchy but instead a lens through which evidence is viewed. Taken with permission from^{(Reference Murad, Asi and Alsawas14)}.

Fig. 3. An example of a framework for ranking evidence evaluating healthcare interventions. Taken with permission from^{(Reference Evans13)}.

It is crucial that consideration is given to the purpose of the research, as well as the strengths and limitations, interpretation and misinterpretation of any hierarchy of evidence used. It is important to note that study designs ranked lowest in any hierarchy may still be the best available for the required purpose of the research. Guidelines necessarily must use the ‘best available evidence’, and this may include low-quality studies if these are the only studies available. It is also important to acknowledge that methods that are inappropriate for assessing efficacy, may still be highly appropriate for assessing some aspects of effectiveness such as feasibility or acceptability (Fig. 3). For example, randomised trials have demonstrated that exclusive enteral nutrition is an effective treatment for active Crohn’s disease, especially in children, but may also be used in adults who wish to reduce steroid exposure^{(Reference Narula, Dhillon and Zhang15)}. However, in adults a cross-sectional survey of clinical case notes has shown that in practice exclusive enteral nutrition is commonly ceased early due to poor compliance^{(Reference Lomer, Gourgey and Whelan16)} and qualitative interviews with patients with Crohn’s disease have reported poorer acceptability due to social restrictions and dietary monotony^{(Reference Mutsekwa, Edwards and Angus17)}. Therefore, although cross-sectional surveys and qualitative interviews would provide poor evidence of the effectiveness of an intervention, they may considerably improve understanding of feasibility and acceptability and contribute to improving the effectiveness of interventions when applied in practice (Fig. 3).

Mechanistic studies are particularly important in determining whether findings from observational cohort studies can be strengthened by supportive evidence for plausible biochemical or physiological mechanisms. They also increase the certainty of evidence from RCT by demonstrating observed effects are operating through a well-understood pathway^{(Reference Williams18)}.

Observational studies, including large and diverse populations, provide evidence of effects at scale and over long periods^{(Reference Katz, Karlsen and Chung19)} and may be the only practicable form of assessing the potential impact of a particular diet or nutrient (the exposure) on a health outcome, where an RCT is not feasible. For example, an RCT intervention may require unfeasibly lengthy follow-up (e.g. effect of fibre on risk of mortality from colorectal cancer), result in unacceptable ethical issues (e.g. where a ‘no intervention’ would be ethically unjust) or is too costly to undertake. These challenges mean that as well as use of cohort data, it is sometimes necessary, though not ideal, to use ‘real-world’ evidence to inform practice. Maduri et al. (2021) discuss this in relation to the use of ‘artificial intelligence’ to make predictions from real-world data collected from patient groups.

These mechanistic and observational studies can make some contribution to supporting the findings from intervention studies when RCT are few in number or low in quality. Not all RCT are well-designed and therefore a poorly designed RCT (e.g. one that is underpowered, poorly blinded, incompletely analysed, with high risk of bias) should not be automatically considered superior to a well-designed cohort study (e.g. one that is adequately powered and includes comprehensive assessment of incident disease, high-quality measurement of nutrient intake, extensive adjustment for confounding variables). Critical appraisal of the individual study methods is required to make these judgements, and this is discussed in the next section. Clinical guidelines increasingly differentiate between higher- and lower-quality study methods in making recommendations (discussed later in this paper). Some hierarchies of evidence have been modified to acknowledge the variation in quality (Fig. 2(b)).

The place of systematic reviews at the top of hierarchies of evidence has also been challenged, because the amalgamated findings are only as good as the rigour of the systematic review itself (strength of search terms, comprehensive search strategy, relevant eligibility criteria etc) and the design of the individual studies included. However, a systematic review of case-control studies (a weak study design) cannot provide the same level of evidence certainty as a systematic review of RCT^{(Reference Murad, Asi and Alsawas14)}. Therefore, modified hierarchies of evidence that place systematic reviews as a method of analysing other methodologies have been proposed (Fig. 2(c))^{(Reference Murad, Asi and Alsawas14)}.

N-of-1 trials involve an individual undergoing routine care who is allocated to both intervention and control, and in the most rigorous design, these are delivered in random order and blinded to both the participant and the researcher, while response is carefully monitored. N-of-1 trials have been proposed in nutrition and dietetic practice^{(Reference Johnston, Seivenpiper and Vernooij6,Reference Potter, Vieira and de Roos20)} as they can account for personalised responses to intervention that an RCT in a large population cannot and of course can be performed at limited cost in the absence of an available RCT^{(Reference Guyatt, Sackett and Taylor21)}. However, such trials are rarely performed in routine clinical practice due to challenges of blinding interventions to both participant and researcher and the time to complete the trials means they are largely restricted to chronic disorders^{(Reference Johnston, Seivenpiper and Vernooij6)}.

Finally, qualitative research (e.g. semi-structured interviews and focus groups) and mixed methods are increasingly used in nutrition and dietetics. Although the purpose of qualitative research is not to measure the quantitative impact of an intervention, but rather to explore experience and perceptions, it is crucial in understanding acceptability and feasibility in routine care, an essential component of evidence-based practice^{(Reference Moisey, A Campbell and Whitmore22)} and included explicitly in some hierarchies (Fig. 3).

Assessing the quality of study methods

As well as understanding the optimal methodological study design, critical appraisal should also involve understanding the strengths and limitations of the individual study methods and their risk of bias. RCT have the lowest risk of bias but there are some unique challenges that are hard to overcome in nutrition and dietetic research, including conducting the ‘gold-standard’ RCT.

Firstly, true blinding can be difficult to achieve in studies of diet or foods because of the difficulties in providing adequate controls. Placebos are possible for micronutrient supplementation trials, but much more difficult to develop for food supplementation or diet modification studies^{(Reference Staudacher, Yao and Chey23)}. Domiciled feeding studies or complete meal provision studies may be able to overcome blinding issues but are extremely expensive and do not reflect how dietary change would occur in real life^{(Reference Hall24)}. Sham dietary advice is an alternative (and can be ethical in certain circumstances) but must ensure that the sham advice is similar in complexity and cost to the intervention diet, and yet does not result in significant change to nutrient intake^{(Reference Staudacher, Irving and Lomer25)}. Alternatively, ‘standard care’ can be used in the form of basic nutrition information (e.g. general healthy eating advice), but if such advice could affect the outcome then the study would need to be comparative and ideally using an RCT^{(Reference Hoy, Winters and Chlebowski26)}.

Secondly, adherence to either intervention or comparison is rarely 100 % even with a simple intervention such as supplements, and therefore, the threshold for an effect may not be reached and thus the expected effect size may not be achieved. Extensive approaches to improving adherence should be included in dietary research including offering alternative dietary options to satisfy personal, cultural and religious preferences and to involve potential participants in the design of the research. These studies require significant resource and skilled individuals which greatly increase their costs.

Third, diet modification studies that change one component (e.g. low carbohydrate diet) will inevitably affect others (e.g. increase fat, reduce fibre) and therefore the nutrient responsible for the effect often cannot be identified. Dietary collinearity (the positive or negative association of the intake of one nutrient with another) is an important potential confounder in research studies and should be carefully monitored^{(Reference Staudacher, Yao and Chey23)}. Collinearity may be particularly important in whole diet interventions that intervene with several potentially synergistic components, rather than isolated nutrient or food interventions^{(Reference Staudacher, Yao and Chey23)}. For example, a study of a gluten-free diet may result in some participants doing more cooking from scratch (improving the nutritional profile of foods eaten), whereas in other participants it may encourage them to purchase pre-prepared meals labelled as gluten-free (increasing the intake of relatively energy-dense and micronutrient poor foods). This introduces variability into the intervention which may reduce the power and efficacy of the study.

Many tools have been developed to assist in the critical appraisal of different study designs and study methods as shown in Table 2 ^{(Reference Zeng, Zhang and Kwong29)}, but despite the specific challenges in nutrition and dietetics there are few tools designed for nutrition trials. However, review papers that raise these issues can be a useful resource to support the evidence-based practitioner in evaluating challenging aspects of critically appraising the methods of dietary intervention studies^{(Reference Staudacher, Yao and Chey23–Reference Staudacher, Irving and Lomer25,Reference Shanahan, McMaster and Staudacher30)} .

Table 2. Examples of critical appraisal tools for use with different study designs

AMSTAR-2, A MeaSurement Tool to Assess systematic Reviews; CASP, Critical Appraisal Skills Programme; NICE, National Institute for Health and Care Excellence; ROB-2, Risk of Bias-2.

Experts in nutrition and dietetics, such as dietitians and nutritionists, should have skills in research design, conduct and analysis, and evidence-based practice including critical appraisal. Competency in these areas is included in standards set by professional associations or governing bodies across the globe, including Australia⁽³¹⁾, Canada⁽³²⁾, the UK^(33,34) and USA^{(Reference Andersen, Baird and Bates35)}. Despite this, studies report variable levels of research involvement^{(Reference Harrison, Brady and Kulinskaya36)} and application of evidence-based practice among dietitians^{(Reference Byham-Gray, Gilbride and Dixon37)}, with few studies specifically in nutritionists. Studies consistently cite barriers including a lack of time and funding, and lack of confidence in research and evidence-based practice. Approaches are needed to increase education and involvement in research and evidence-based practice during university programmes in nutrition or dietetics^{(Reference Whelan, Castelli and Trizio38)} and once in practice^{(Reference Slawson, Clemens and Bol39)}, as well as improving research collaboration and funding in nutrition^{(Reference Mathers40)}.

Assessing certainty using the GRADE method

There are various methods to assess certainty of a collective body of evidence. The GRADE method (Grading of Recommendations, Assessment, Development and Evaluation) is a widely used framework that helps researchers and guideline developers rate evidence quality in studies and grade the strength of guideline recommendations^{(44,Reference Guyatt, Oxman and Schünemann45)} . The intent is to determine the level of certainty in the evidence, whether the intervention or exposure is effective or not. How evidence is rated has potentially substantial implications as to how knowledge is applied in clinical practice, hence a rigorous and widely accepted assessment tool like GRADE is critical to produce high-quality systematic reviews and guidelines. The GRADE method assigns four levels for evidence certainty: high, moderate, low and very low^{(Reference Guyatt, Oxman and Kunz46)}. When using GRADE in systematic reviews, ‘Summary of Findings’ tables are developed and certainty of evidence is determined^{(Reference Guyatt, Oxman and Akl47)}.

The GRADE’s evidence-to-decision framework is used to consider evidence and other specific elements in formulating guideline recommendations⁽⁴⁸⁾. GRADE classifies guideline recommendations as strong or weak. A strong recommendation indicates that most patients should receive the intervention as the recommended course of action, while a weak recommendation may mean that different choices will be appropriate for different patients based on patients’ values and preferences. Different recommendation examples are shared later in the section on the Evidence Analysis Library (EAL).

Although judgments and deliberation are required, the systematic and transparent GRADE approach provides a structured framework to engage in the necessary judgements and reach rating decisions. To apply the GRADE method, specialised training is recommended. As a starting point, Cochrane offers online introductory courses and resources to learn more about the GRADE method and create summaries of findings (https://training.cochrane.org/). The most comprehensive resource on the GRADE method is the GRADE handbook⁽⁴⁸⁾.

Evidence Analysis Library® of the academy of nutrition and dietetics

In this section, we describe the guideline development methods of the AND^{(Reference Papoutsakis, Moloney and Sinley62,65)} . Since 2004, the AND has published evidence-based nutrition practice guidelines (referred to as guidelines thereafter) to support the practice of nutrition and dietetic professionals who strive to provide evidence-based, effective and safe nutrition care. The source of funding is primarily AND whose guidelines do not receive industry funding. The guidelines are a collection of action-oriented practice recommendation statements that are based on a systematic review^{(Reference Handu, Moloney and Wolfram64)}, using a process which integrates the GRADE method. The guidelines are organised by the nutrition care process model and may focus on one or more steps of this process^{(Reference Swan, Vivanti and Hakel-Smith63)}. The nutrition care process model encourages people-centred care and ongoing research of nutrition care outcomes. The guideline development method is summarised in Fig. 4 and further details are provided in Table 4. A comprehensive evidence analysis manual describes detailed workflows and provides forms for evidence synthesis projects⁽⁶⁷⁾.

Fig. 4. Evidence analysis library guideline development process. This rigorous and transparent multi-step method to develop guidelines^{(Reference Papoutsakis, Moloney and Sinley62)} is described in detail in a series of learning modules (in five short videos) (www.andeal.org/tutorials).

Table 4. Five components of evidence-based nutrition guidelines produced by the Evidence Analysis Library, academy of nutrition and dietetics

The selection of topics for new guidelines is determined by criteria established by the AND’s Council on Research and includes a needs assessment and evaluation component of existing guidelines. Typically, a guideline team comprises methodologist, lead analyst, project manager, six to eight subject experts and patient advocate and/or patient organisation representative whenever possible.

Recommendations are rated using the GRADE rating system (1), strong (we recommend); (2) weak (we suggest)) and the certainty of evidence assigned according to the evidence the recommendation is based on (A, high; B, moderate; C, low; D, very low), for example 1A means a strong recommendation based on a high certainty of the evidence^{(65,Reference Andrews, Guyatt and Oxman68,Reference Andrews, Schunemann and Oxman69)} . For example:

An example of a weak recommendation based on low certainty of evidence would be:

The process consists of an internal and external review of the draft guideline (Table 4 & Fig. 4). Reviewers include, but are not limited to, nutrition and dietetics practitioners, physicians, nurses, pharmacists and psychologists. The AGREE II instrument^{(Reference Brouwers, Kho and Browman70)} is used for evaluation. Any recommendation statements changed during the review process are voted on and approved by the subject matter experts on the project.

Following external review, other stakeholders may highlight concerns surrounding feasibility of the recommendations, patient-centred language and other important factors. In recent guideline projects, to obtain end user feedback on the applicability of a guideline, practitioners were recruited, provided with a general guideline orientation and asked to test the guideline in their practice for two weeks. Recruited practitioners then came together in a focus group to describe their own experiences and their clients’ feedback. The project team reviews the feedback and addresses comments while maintaining the integrity of the evidence. The goal is to generate a comprehensive guideline (as summarised in Table 4) and a practitioner guide (shortened version or infographic, that uses language that can help communicate research to clients and is intended for use with clients for shared decision-making). An example practitioner guide (on saturated fat) can be found here: https://www.andeal.org/files/files/Saturated%20Fat/2023–07_DLM-SF_PractitionerGuide_2023_01_25.pdf and the respective comprehensive guideline is here: https://www.andeal.org/topic.cfm?menu=3693&cat=6214. There is a growing emphasis on developing information on ‘implementation considerations’ that are rich and detailed with tools and pragmatic suggestions. Guideline implementation may need aligned efforts between stakeholders and systems-focused approaches to implement change at the organisational level. To assist practitioners with these considerations, the EAL provides an implementation guide manual (that can be found here: https://www.andeal.org/vault/2440/web/files/EAL/EAL_Guideline_ImplementationManual_2022Nov.pdf)

The AND Council on Research provides final approval that the EAL project team has appropriately addressed all the comments received. The final guideline is then published on the EAL subscription website (www.andeal.org). Guidelines and supporting systematic reviews are also published as separate manuscripts in peer-reviewed journals. The AND’s guidelines are recognised and referenced by the Guidelines International Network (https://g-i-n.net/).

Historically, the AND guidelines are revisited every five years. A scoping review is carried out to help inform authoritatively whether substantial literature has been published on the topic since the last systematic review. The Council on Research, supported by the EAL staff, determines which recommendations of the guideline should be revised. To reduce duplication and maximise efficiency of resources inter-agency partnerships are sought. As an example, the recent update of the chronic kidney disease guideline was completed in collaboration with the National Kidney Foundation. It describes 83 recommendations on important nutrition topics in chronic kidney disease, including nutrition screening and assessment; medical nutrition therapy; protein and energy intake; micronutrients; electrolytes; nutritional supplementation; and dietary patterns (Handu et al. 2021).

Recently, EAL staff have followed the stages of GRADE-ADOLOPMENT. Adolopment here refers to evaluating and then adopting ‘as is’ or adapting existing guidelines instead of creating guidelines from the ground up. The GRADE-ADOLOPMENT process helps researchers decide transparently and systematically whether it is appropriate to adapt or adopt existing recommendations from other organisations in order to expedite the generation of recommendations that are current, rigorous and evidence-based^{(Reference Schünemann, Wiercioch and Brozek71)}.

Wide dissemination and implementation of guidelines is necessary to deliver quality care and improve targeted health outcomes. To this end, the AND conducts research on the use of guidelines and resulting outcomes. This is an emerging process in which the recommendations are ‘operationalised’ using the nutrition care process, related terminology and informatics tools^{(Reference Swan, Vivanti and Hakel-Smith63,Reference Lamers-Johnson, Kelley and Sanchez72–Reference Swan, Pertel and Hotson74)} . Such efforts intend to support guideline adoption and allow longitudinal monitoring of guideline application.

Practice-based Evidence in Nutrition® (PEN)

The PEN System is an online nutrition knowledge translation platform that is jointly managed by Dietitians of Canada, the British Dietetic Association and Dietitians Australia^{(Reference Neale and Tapsell75)}. It is funded by subscription revenue and does not accept funding from industry or advertising. Developed in 2005 as a way of creating and managing a dynamic, online clinical nutrition manual, it has now grown to provide evidence-based practice guidance for more than 1000 practice questions in over 200 topic areas, including those related to population health, health conditions, food and nutrients and professional practice. The PEN team does not create independent clinical practice guidelines, but rather develops practice recommendations using the best evidence available. This evidence might arise from clinical practice guidelines (or sometimes multiple sets of guidelines developed by different groups), or it might come from secondary research studies, primary research studies, grey literature that provides additional practice context or a combination thereof. Using this adaptable approach to seek the ‘best available evidence’ the PEN System aims to enhance evidence use by practitioners. Content on the PEN System is internationally peer-reviewed by academic and practice-based experts.

Practice guidance on the PEN System is developed using the five ‘A’s model of evidence-based practice^{(Reference Sackett, Rosenberg and Gray5,Reference Straus, Glasziou and Richardson76)} : assess, ask, acquire, appraise and apply (Fig. 1(b)). An overview of the PEN process is provided in Fig. 5. The first ‘assess’ stage uses an algorithm developed for this purpose^{(Reference Royall, Armour and Bellman77)}. In the second stage (Ask), ‘foreground’ questions are emphasised, that is questions that address issues of care and/or decision-making and focus on assessment, treatment and prevention, rather than ‘background’ questions, which focus on aetiology, prevalence, incidence, prognosis or disease course⁽⁷⁸⁾. The ‘acquire’ stage uses a systematic approach executed by an Evidence Analyst⁽⁷⁹⁾. The appraisal stage uses an Evidence Grading Checklist⁽⁸⁰⁾, which categorises evidence on a scale of A to D. A-level conclusions are supported by GOOD evidence, B-level conclusions supported by FAIR evidence, C-level conclusions supported by LIMITED evidence or expert opinion and for a D-level rating conclusions cannot be drawn or extremely limited because evidence is unavailable, poor quality or contradictory.

Fig. 5. Schematic representation of the PEN process for developing practice recommendations and tools. PI(E)CO(TS): Population or Problem, Intervention or Exposure, Comparison, Outcome, Timeframe, Setting or Study Design.

An example of a practice question with Key Practice Points is shown in box 2, including a recommendation, summary of the evidence and remarks that identify implementation considerations or help contextualise the recommendation for different regions, settings or sub-populations⁽⁸¹⁾. In addition, summaries and critical appraisal of the individual articles used to create the recommendation, and comments and rationale are provided. These provide further information to support practice (e.g. food sources of a nutrient of interest) or proposed mechanisms of action.

Box 2. An example of a practice question with Key Practice Points.

Finalised content is further translated into knowledge products designed to support practice, such as client-focussed handouts and practice guidance toolkits, which outline key considerations related to the assessment, diagnosis, intervention and monitoring of health conditions in a format consistent with nutrition care process terminology⁽⁸²⁾.

EAL and PEN offer two examples of guideline development for nutrition interventions and illustrate the significant progress made in the last decade, but there is less certainty about how or whether practitioners adopt and use guidelines. There is some evidence that guidelines are not implemented fully in practice and further research to understand the barriers and facilitators to guideline implementation is needed. As mentioned in the previous section, this is now one focus of the AND work programme.

Those who deliver nutrition interventions to individuals

1. 1. An evidence-based approach to delivering nutrition interventions is crucial to ensure the intervention is efficacious and most likely to be acceptable, effective and safe. Nevertheless, it is important to recognise that the highest levels of evidence are sometimes not possible to achieve due to the nature of research in nutrition and diet, in humans. Therefore, the concept of using the entirety of the best available evidence should be applied in prescribing nutrition interventions in individuals by nutrition and dietetic professionals.

2. 2. Nutrition and dietetic curriculums and competencies should be continually examined and reviewed to ensure nutrition and dietetic professionals are trained in the skills outlined in this paper:

   a. reviewing, critiquing and applying best available research evidence for nutrition interventions in individuals

   b. identifying where research evidence is lacking and having the skills to design and conduct research to fill these gaps

   c. understanding systematic reviewing and guideline development processes so these are undertaken routinely, and the best available evidence is applied to practice

3. 3. Nutrition and dietetic professionals should be trained and maintain their competency to combine all relevant factors when advising clients in the context of the best available evidence (e.g. cultural, personal, medical, environmental, societal).

4. 4. Leadership is required from professional bodies to acknowledge and pursue evidence-based practice. This includes raising awareness of high-quality dietary information, particularly with policy-makers and other stakeholders. Continued efforts are needed to promote nutrition and dietetic professionals as the best source of nutritional and dietary information and guidance, as they have the skills required to navigate the complexity of applying evidence to individualised care. Targeted outreach campaigns that aim to increase awareness and build trust could be important approaches that professional bodies may pursue systematically.

Those funding, commissioning or undertaking research

1. 1. Patient and public involvement and engagement should be prioritised and included as part of funding criteria for future nutrition-related research. It is crucial in priority setting and research design to ensure patient values, preferences and experiences are incorporated.

2. 2. Research is needed to understand the barriers and facilitators to guideline implementation, and priority should be given to this area. Now that defined systematic processes have been created to develop high-quality guidelines, work is needed to ensure that they can be implemented and applied in clinical practice to ensure patients receive care based on the best possible evidence.

3. 3. A greater understanding of the most robust research designs for use in nutritional interventions aimed at individuals is required. The development of a hierarchy of evidence specifically for nutrition studies for individualised care is needed, which reflects the concepts of study quality, best available evidence and individualisation.

4. 4. Understanding the extent of nutrition misinformation and identifying solutions to tackle it is a key research priority. We need to understand what sources of nutrition information people use, the quality of the information provided from different sources, and where the highest risk of misinformation lies. There is a need to help different groups (patients, public, policy-makers, other healthcare professionals etc) to distinguish between ‘good’ and ‘bad’ information and identify sources of high-quality information, such as the promotion of health information certification schemes⁽¹¹⁵⁾.

Those disseminating nutritional information

1. 1. People conveying research findings or other nutritional information should acquire the skills to interpret scientific data (or work closely with professionals who have these skills) and identify sources of trusted reliable information. As this paper has detailed, nutrition and dietary advice to individuals is rarely simple. Those disseminating nutritional information need to ensure they are able to provide safe, useable, relevant dietary information to individuals.

2. 2. Trusted and reliable sources of information for individualised advice include professionals who are suitably qualified, having the in-depth understanding of the evidence and the skills to critically evaluate it, and practice under a code of ethics, such as dietitians and nutritionists who are credentialled with their national authority or registration body. These professionals should be the preferred source of information.