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Indicators of nutritional risk in hospital inpatients: a narrative review

Published online by Cambridge University Press:  10 December 2021

Alison Yaxley Open the ORCID record for Alison Yaxley [Opens in a new window] ,
Reegan K. Knowles ,
Sebastian H. Doeltgen ,
Diane J. Chamberlain ,
Raechel A. Damarell  and
Michelle D. Miller
Alison Yaxley*
Affiliation:
College of Nursing and Health Sciences, Flinders University, PO Box 2100, Adelaide, SA 5001, Australia
Reegan K. Knowles
Affiliation:
College of Nursing and Health Sciences, Flinders University, PO Box 2100, Adelaide, SA 5001, Australia
Sebastian H. Doeltgen
Affiliation:
College of Nursing and Health Sciences, Flinders University, PO Box 2100, Adelaide, SA 5001, Australia
Diane J. Chamberlain
Affiliation:
College of Nursing and Health Sciences, Flinders University, PO Box 2100, Adelaide, SA 5001, Australia
Raechel A. Damarell
Affiliation:
College of Nursing and Health Sciences, Flinders University, PO Box 2100, Adelaide, SA 5001, Australia
Michelle D. Miller
Affiliation:
College of Nursing and Health Sciences, Flinders University, PO Box 2100, Adelaide, SA 5001, Australia
*
*Corresponding author: Alison Yaxley, fax +618 8204 6406, email alison.yaxley@flinders.edu.au

Abstract

Malnutrition is common in the acute care setting. Despite the existence of a plethora of screening tools, many malnourished patients remain undiagnosed and untreated, in part due to competing responsibilities for screening staff, under- or over-referral to dietetics services, and inadequate dietetics resources. Better identification of patients at risk of malnutrition would enable optimised care provision and streamlined care pathways. This narrative review of reviews aimed to collate and synthesise literature documenting nutritional risk factors in adult hospital inpatients, to generate a comprehensive list of nutritional risk indicators from high methodological quality review articles. Six electronic databases were searched (Medline, Cumulative Index to Nursing and Allied Health Literature, Cochrane Database of Systematic Reviews, Joanna Briggs Institute Database, Embase and Scopus) using a systematic search strategy. Three researchers screened the resulting 5889 citations, identifying 59 reviews summarising original studies that investigated associations between indicators and measures of malnutrition, undernutrition or nutritional risk. After quality appraisal by two researchers, using the American Dietetic Association Quality Criteria Checklist for Review Articles, seven reviews were classified as high quality, identifying fifty-seven unique indicators of nutritional risk (disease status/condition – twenty-three; eating/appetite/digestion – twelve; type of diet – five; cognition/psychology/social factors – five; medication-related – two; miscellaneous – ten). This is the first comprehensive list of nutritional risk factors in adult hospital inpatients, derived from only the highest methodological quality reviews. This list contributes to the development of practice and evidence-informed systems-level approaches to the identification of nutritional risk in the acute care setting.

Keywords

Acute careAdultIndicatorsInpatientsNutritional riskPhrasesReview
Type
Review Article
Information
Journal of Nutritional Science , Volume 10 , 2021 , e104
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Malnutrition is common in the acute care setting with an estimated prevalence of 20–50%, depending on the method of diagnosis and specific patient group(Reference Barker, Gout and Crowe1). Malnutrition can exist pre-admission, worsen during admission and/or develop during a hospital stay(Reference Barker, Gout and Crowe1). The presence of malnutrition is an independent risk factor for a range of negative patient outcomes, including increased length of hospital stay(Reference Allard, Keller and Jeejeebhoy2), poor wound healing, functional decline and adverse psychosocial outcomes(Reference Saunders3). In addition to poor patient outcomes, it has been estimated that malnutrition costs the global economy US$3⋅5 trillion per year(4).

In order to implement timely and appropriate nutritional support, dietitians can conduct a comprehensive clinical assessment, or complete one of several validated malnutrition assessment tools, e.g. the Subjective Global Assessment(Reference Miller, Wells and Nwulu5), to thoroughly investigate a patient's nutritional status and determine their individual nutritional needs. However, the time-consuming and resource-intensive nature of nutritional assessment often means that not all patients can be assessed during their hospital stay. Therefore, a number of malnutrition screening tools have been developed to quickly identify patients at risk of malnutrition and enable timely referral for comprehensive assessment by dietetics staff(Reference Baker, Detsky and Wesson6). These tools may be performed by any healthcare worker, relieving workforce burden on dietitians. Commonly, they focus on only a few markers of nutritional status, such as BMI, weight loss and clinical condition, e.g. the Malnutrition Universal Screening Tool (MUST)(Reference Elia7).

Despite the high prevalence of malnutrition, its serious consequences and the number of screening tools available to identify at-risk patients, malnutrition in the acute setting often remains underdiagnosed and undertreated(Reference Elia7). Proposed reasons for this include inconsistent policies related to malnutrition screening(Reference Cant8), competing priorities of hospital staff and lack of adequate staff training(Reference Porter, Raja and Cant9,Reference Raja, Gibson and Turner10) . Furthermore, even patients that are screened for malnutrition may not be identified as being at risk because the need for screening tools to be simple and time effective does not allow for consideration of a broad range of risk factors, or for objective measurement of factors influencing nutritional risk. Finally, even if patients are flagged as at risk, they may not be assessed by a dietitian despite positive screening and referral, as limited dietetic resources necessitate prioritisation of cases(Reference Porter and Jamieson11). This issue is compounded by over-referral due to the lack of sensitivity of some screening tools(Reference Phillips and Zechariah12). The significant limitations in the existing malnutrition screening, assessment and diagnosis processes result in suboptimal identification and management of malnutrition in acute care settings.

One of the main limitations of contemporary malnutrition screening tools is that they do not consider the large range of nutritional risk factors outside of the physical and anthropometric measures commonly considered by existing tools. Such factors include aspects of the hospital environment, surgery status, behavioural difficulties, support at meal time, therapeutic diets (e.g. nil-by-mouth, pureed, etc.), and food options and taste preferences(Reference Raynaud-Simon, Reval-Delhom and Hebuterne13). In addition, multiple indicators may combine to influence relative risk on an individual basis. However, to date, no systematic interrogation of the literature has been undertaken to identify and collate previously documented indicators of nutritional risk. A comprehensive understanding of all the factors identified to date which modulate malnutrition risk would provide a basis from which novel, innovative, systems-based screening pathways could be developed that more comprehensively and holistically assess an individual patient's risk for malnutrition. In an era of individualised, patient-centred and budget-conscious health care, such novel triage systems would contribute to optimised referral, assessment and care pathways.

In order to collate and synthesise existing literature documenting nutritional risk factors, we performed a narrative review of reviews, utilising a systematic literature search strategy, to investigate the association between indicators and nutritional risk in adult inpatients.

Methods

Registration

This narrative review has been registered (PROSPERO 2018 CRD42018105464).

Data sources and search strategy

An experienced research librarian (RD) searched Medline (Ovid), Cumulative Index to Nursing and Allied Health Literature (CINAHL), Cochrane Database of Systematic Reviews, Joanna Briggs Institute Database, Embase (Ovid) and Scopus for reviews in the English Language, published up to May 2019. A large number of search terms for each concept of relevance to the topic were used to locate studies. These concepts were the acute setting (hospitalised, inpatient), risk in general (risk, determinants, predisposing factors) and nutritional risk status specifically (malnutrition, vitamin deficiency). The search strategy was first developed for Ovid Medline (Supplementary Table S1) and then translated for each of the other target databases. Reference lists of selected articles were hand-searched to identify further articles.

Screening and review selection

After removal of duplicates, the articles located were imported into Covidence, an online software program that facilitates study selection(14). At least two researchers (AY, MM or RK) independently examined titles and abstracts to select articles for full-text screening. Conflicts were resolved by discussion between the original screeners or by a third researcher. Relevant review articles were obtained in full text. Two researchers (AY and RK) independently examined the full-text articles against the inclusion and exclusion criteria. Again, inter-reviewer disagreement on inclusion of particular articles was resolved through discussion.

Inclusion criteria

  • English language;

  • Type of study: Review articles that summarised any type of study design, including RCTs, observational studies, case-control or other quasi-experimental studies;

  • Study populations: Adult (aged ≥18 years) hospital inpatients; and

  • Review articles summarising original studies that investigated an association between an indicator and a measure of malnutrition, undernutrition or nutritional risk.

Exclusion criteria

All other articles as well as reviews not meeting pre-defined criteria for methodological quality.

Quality appraisal

Two reviewers (AY and RK) appraised the quality of included articles as being either positive, negative or neutral, using the American Dietetic Association (ADA) Quality Criteria Checklist for Review Articles(15). Given the large number of reviews (and therefore indicators) located, and the objective to focus on indicators supported by high-quality evidence, only reviews classified as positive (indicating that the report clearly addressed issues of inclusion/exclusion bias, generalisability, and data collection and analysis) were included in this qualitative synthesis.

Data extraction

For each included review, one researcher (RK) extracted from the full text those risk indicators that were assessed as being associated with at least one of the outcome variables (i.e. malnutrition, undernutrition or nutritional risk).

Results

The initial literature search yielded a total of 5889 citations (see Fig. 1). Following the removal of duplicates, title, abstract and full-text screening, fifty-nine reviews were selected for quality appraisal. Seven articles were identified as ‘positive’ according to the ADA Quality Criteria Checklist for Review Articles and therefore included in the current review(Reference Raynaud-Simon, Reval-Delhom and Hebuterne13,Reference Chen, Li and Fang16Reference Tenner, Baillie and Dewitt21) .

Fig. 1. Flowchart of the findings of the search and screening process for a literature review to identify reviews reporting nutritional risk indicators in adult acute care inpatients.

Fig. 1 shows that fifty-two potentially eligible reviews were excluded due to not meeting quality criteria. The most common limitations identified across the excluded reviews were that the processes for extraction, synthesis and analysis of data were not clearly described, and quality appraisal of articles was not completed or was not clearly reported. In addition, biases and limitations did not appear to have been taken into consideration in the conclusions reported. The seven high-quality studies included in the final analysis were assessed using the NHMRC hierarchy of evidence(22), and considered Grade 1. This is the highest grade of research evidence and commonly used to suggest that evidence can be trusted to guide practice.

From the seven included reviews, a total of fifty-seven unique indicators were identified as being associated with nutritional risk (see Table 1). Twenty-three of these indicators are related to a disease status or condition (stroke (seven separate indicators were identified regarding stroke, i.e. stroke with several associated conditions/circumstances were investigated), cancer, psoriasis, acute pancreatitis, Parkinson's disease, chronic alcoholism, depression, dementia, ear, nose and throat disease, infectious disease, inflammatory disease, organ failure, gastrointestinal disease, neurodegenerative disease, vascular disease, fracture and oropharyngeal candidiasis); twelve are related to eating, appetite or digestion (dysphagia, dysgeusia, anorexia, dental hygiene, dentures, chewing, dry mouth, reduced food intake, eating impairment, malabsorption, maldigestion and severe constipation); five were types of diets (slimming, diabetic, residue-free, salt-free and cholesterol-lowering); five describe altered cognition/psychology or social factors (drowsiness, delirium, altered level of consciousness, grieving and social isolation); two are medication-related (polypharmacy, long-term use of corticosteroids) and remaining indicators include energy requirements, pressure sores, pain, financial difficulties, ill-treatment, lifestyle change, behavioural disorders, adductor pollicis muscle thickness, surgery and mobility impairment. Stroke-related dysphagia was the only indicator identified in more than one review, and dysphagia independent of stroke was also identified by one study.

Table 1. Characteristics of articles included in a review of reviews reporting nutritional risk indicators in adult acute care inpatients

Abbreviations: n, number; OR, Odds Ratio; CI, Confidence Interval; P, P-value; BMI, Body Max Index; PG-SGA, Patient-Generated Subjective Global Assessment; ROC, Receiver Operator Characteristic.

Included articles were published between 2001 and 2017 in seven different countries (France(Reference Raynaud-Simon, Reval-Delhom and Hebuterne13), China(Reference Chen, Li and Fang16), Brazil(Reference Fruchtenicht, Poziomyck and Kabke17), Singapore(Reference Lew, Ong and Miller18), Denmark(Reference Miller, Ellervik and Yazdanyar19), the UK(Reference Perry and Love20) and the US(Reference Tenner, Baillie and Dewitt21)). Two reviews did not report the number of original articles reviewed or the total number of participants(Reference Raynaud-Simon, Reval-Delhom and Hebuterne13,Reference Tenner, Baillie and Dewitt21) , however across the remaining reviews, a total of 122 original articles were included, with a total of 30 202 439 participants. Although not all reviews reported the study designs of the included original research, those that did indicated that they were all observational designs, including cohort, case-control and cross-sectional designs. All reviews investigated the association between potential indicators and malnutrition in adult hospital inpatients, with five focusing on the relationship in cohorts with a diagnosed disease (two cohorts had experienced stroke(Reference Chen, Li and Fang16,Reference Perry and Love20) , one cancer(Reference Fruchtenicht, Poziomyck and Kabke17), one acute pancreatitis(Reference Tenner, Baillie and Dewitt21) and one psoriasis(Reference Miller, Ellervik and Yazdanyar19)). Reynaud-Simon and colleagues(Reference Raynaud-Simon, Reval-Delhom and Hebuterne13) investigated indicators in the elderly hospitalised (>70 years) population, while Lew and colleagues(Reference Lew, Ong and Miller18) included all hospitalised adults. Across the reviews, a range of outcomes were measured as proxy indicators of malnutrition/nutritional status, with some reviews not specifying these outcome measures(Reference Raynaud-Simon, Reval-Delhom and Hebuterne13,Reference Chen, Li and Fang16,Reference Tenner, Baillie and Dewitt21) . The measures in the remaining four papers included biochemical measures(Reference Fruchtenicht, Poziomyck and Kabke17,Reference Miller, Ellervik and Yazdanyar19,Reference Perry and Love20) , weight, BMI and anthropometric measures(Reference Fruchtenicht, Poziomyck and Kabke17,Reference Perry and Love20) , time to return to normal diet(Reference Perry and Love20), malnutrition assessment tool(Reference Fruchtenicht, Poziomyck and Kabke17,Reference Lew, Ong and Miller18) and indirect calorimetry(Reference Fruchtenicht, Poziomyck and Kabke17).

Discussion

While there is a plethora of literature reporting on nutritional risk and malnutrition, there is a need to be confident in the quality of the published evidence to guide clinical decision making. This narrative review of reviews is the first to extract a comprehensive list of nutritional risk factors in adult acute care inpatients, from only the highest quality review articles, which will contribute to the development of automated practice and evidence-informed systems-level approaches to the identification of nutritional risk in this setting.

Following a systematic literature search strategy, seven reviews of high methodological quality presenting evidence for fifty-seven indicators of nutritional risk were identified. This narrative review has highlighted the lack of high-quality evidence in this area. Nonetheless, the large number of indicators identified demonstrates that maintenance of adequate nutrition is highly multifactorial and influenced by a wide range of diseases and symptoms, personal circumstances, environments, treatments and psychological factors. Interestingly, there was little overlap of risk factors between the included reviews, with stroke being the only factor reported to be associated with malnutrition in more than one study. It is possible that further overlap was present in reviews not included in this narrative review, but our aim was to identify only those indicators presented in high-quality reviews. Furthermore, given that only reviews were included in this narrative review, this suggests that there are likely multiple original studies with consistent findings.

Many of the risk factors identified in this review of reviews are not included in existing, commonly used screening tools and extend beyond the biochemical and anthropometrical measures typically assessed, e.g. the MUST includes body mass index, weight loss and acute disease effect(Reference Elia7), while the Malnutrition Screening Tool includes only unintentional weight loss and poor intake related to decreased appetite(Reference Ferguson, Capra and Bauer23). It is possible that these tools were developed before the high-quality evidence considered in this review was available, or that practical limitations guided the selection of the assessment items included in these screening tools. It is evident from the findings of our review of high-quality reviews, however, that existing tools may not truly identify those at risk of malnutrition. We propose that our findings provide a timely opportunity to revise and re-orient current malnutrition identification and management processes, by automated means.

We acknowledge the need for screening tools to be able to be rapidly conducted and that the large number of risk factors identified in the current review is unlikely translatable into another manual screening tool of this type. We foresee that it is more likely that the vast amount of information required to screen for all of the identified risk factors will need to be processed by automated, systems-based algorithms. The development of an automated system that capitalises on the advantages of artificially intelligent machine learning could overcome the otherwise prohibitively time-consuming screening process. A recent scoping review of technology used to identify hospital malnutrition identified few screening tools and those that were located included a limited range of nutrition risk indicators such as weight, height and biochemistry(Reference Trtovac and Lee24). Ultimately, a well-trained system could reliably identify at-risk patients by mining electronic medical records and hospital databases in order to triage patients, on a real-time basis, for dietetic screening, assessment and management. Such a system would represent an opportunity to optimise the use of limited dietetics resources, which has already been identified as a significant barrier to diagnosing and treating malnutrition in the acute setting(Reference Barker, Gout and Crowe1).

The findings of this review of reviews are limited by the lack of eligible high-quality reviews available for inclusion and need to be considered in this context. It is possible that other risk factors exist that to date have not yet been captured in a systematic review and hence are not included in our list of indicators. In addition, some of the reviews(Reference Fruchtenicht, Poziomyck and Kabke17,Reference Lew, Ong and Miller18) were limited by a lack of relevant original articles for inclusion. However, the large number of reviews excluded after quality assessment highlights the need for rigorous study design in research in order that findings can be interpreted with confidence. It was also difficult to make comparisons across the included reviews due to their heterogeneity in terms of indicators investigated, outcome measures reported and data analysis techniques used. This also prohibited the ranking of indicators according to the magnitude of impact on nutrition risk, as well as the potential interplay between different indicators. Furthermore, the reviews included in this narrative review were from seven different countries. While this may be a limitation given the multifactorial nature of malnutrition, these countries represent a broad cross-section of developed countries, thus this may increase the generalisability of findings to the developed world. Finally, each review investigated potential indicators in a different inpatient population (e.g. stroke patients, cancer patients etc.), meaning that the factors listed in our comprehensive list may not predict nutritional risk in all patient populations. Nonetheless, to our knowledge, this is the first attempt to synthesise the abundance of literature on the subject of malnutrition with the aim to generate a thorough list of nutritional risk factors identified from high-quality literature, following a rigorous systematic methodology.

Conclusion

The findings of this review represent the first comprehensive list of risk factors for malnutrition in the acute care setting that is based only on high-quality evidence. The availability of this comprehensive list has the potential to optimise the use of dietetics resources and patient outcomes through the development of novel, holistic, automated, systems-based screening pathways that may be better able to identify and triage patients according to nutritional risk than current tools. In order to develop such novel approaches, more research is needed to identify the magnitude of risk that can be attributed to each of the identified indicators and the interplay between them. While the literature is an important component, clinical expertise is also important and future research will include a consideration of both aspects in the development of systems-level approaches.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/jns.2021.86.

Acknowledgements

The authors acknowledge the support and expertise of the New South Wales (NSW) Ministry of Health Project Advisory Committee and thank them for their input to the design of this literature review.

A. Y., R. K., S. D., D. C., M. M. conceived and designed the review. R. D. developed, translated and conducted literature searches. A. Y., R. K. and M. M. screened literature arising from searches. A. Y. and R. K. conducted quality appraisal of literature. All authors were involved in critical analysis of results. A. Y. and R. K. had primary responsibility for writing the manuscript. All authors reviewed and edited the manuscript and approved the final version.

This literature review was conducted as part of a project commissioned by the NSW Ministry of Health, Australia. The Project Advisory Committee provided input to the identification of search terms for this review. All remaining design, analysis and writing of this article were conducted by the authors.

There are no conflicts of interest.

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Figure 0

Fig. 1. Flowchart of the findings of the search and screening process for a literature review to identify reviews reporting nutritional risk indicators in adult acute care inpatients.

Figure 1

Table 1. Characteristics of articles included in a review of reviews reporting nutritional risk indicators in adult acute care inpatients

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