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Association of postnatal severe acute malnutrition with pancreatic exocrine and endocrine function in children and adults: a systematic review

Published online by Cambridge University Press:  04 May 2022

Farzana Ferdous
Affiliation:
School of Tropical Medicine and Global Health, Nagasaki University, Sakamoto Campus, Nagasaki, Japan Nutrition and Clinical Services Division, International Centre for Diarrhoeal Disease Research, Bangladesh, Dhaka, Bangladesh
Suzanne Filteau
Affiliation:
Faculty of Epidemiology and Population Health, London School of Hygiene and Tropical Medicine, London, UK
Nanna Buhl Schwartz
Affiliation:
Dept of Nutrition, Sports and Exercise, University of Copenhagen, Frederiksberg, Denmark
Sehlulekile Gumede-Moyo
Affiliation:
Faculty of Epidemiology and Population Health, London School of Hygiene and Tropical Medicine, London, UK
Sharon Elizabeth Cox*
Affiliation:
School of Tropical Medicine and Global Health, Nagasaki University, Sakamoto Campus, Nagasaki, Japan Faculty of Epidemiology and Population Health, London School of Hygiene and Tropical Medicine, London, UK Institute of Tropical Medicine, Nagasaki University, Sakamoto Campus, Nagasaki, Japan UK Health Security Agency, 61 Colindale Avenue, London, UK
*
*Corresponding author: Sharon Elizabeth Cox, email sharon.cox@lshtm.ac.uk
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Abstract

Severe acute malnutrition may lead both concurrently and subsequently to malabsorption and impaired glucose metabolism from pancreatic dysfunction. We conducted a systematic review to investigate the associations of current and prior postnatal wasting malnutrition with pancreatic endocrine and exocrine functions in humans. We searched PubMed, Google Scholar, Web of Science and reference lists of retrieved articles, limited to articles in English published before 1 February 2022. We included sixty-eight articles, mostly cross-sectional or cohort studies from twenty-nine countries including 592 530 participants, of which 325 998 were from a single study. Many were small clinical studies from decades ago and rated poor quality. Exocrine pancreas function, indicated by duodenal fluid or serum enzymes, or faecal elastase, was generally impaired in malnutrition. Insulin production was usually low in malnourished children and adults. Glucose disappearance during oral and intravenous glucose tolerance tests was variable. Upon treatment of malnutrition, most abnormalities improved but frequently not to control levels. Famine survivors studied decades later showed ongoing impaired glucose tolerance with some evidence of sex differences. The similar findings from anorexia nervosa, famine survivors and poverty- or infection-associated malnutrition in low- and middle-income countries (LMIC) lend credence to results being due to malnutrition itself. Research using large, well-documented cohorts and considering sexes separately, is needed to improve prevention and treatment of exocrine and endocrine pancreas abnormalities in LMIC with a high burden of malnutrition and diabetes.

Type
Research Article
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, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

Wasting malnutrition remains common both for children in low- and middle-income countries (LMIC) and for adults with severe infections, notably HIV or tuberculosis. As treatments for severe acute malnutrition improve(Reference Ashworth, Khanum and Jackson1) and drugs become increasingly available and effective for severe infections, more people survive but the long-term consequences of their malnutrition are not fully understood(Reference Dalvi, Yang and Swain2,Reference Ibrahim, Zambruni and Melby3) . Acute nutritional deficits during the prenatal period affect the structure and function of organs such as the pancreas which have fundamental roles in metabolism(Reference Dalvi, Yang and Swain2,Reference Calkins and Devaskar4) . While there is information from animal models and from human studies of prenatal malnutrition, usually indicated by a proxy of low birth weight(Reference Dolenšek, Pohorec and Rupnik5), the consequences of postnatal undernutrition on human pancreatic structure and function and later chronic disease development are not well documented.

Both pancreatic endocrine (i.e. production of hormones such as insulin or glucagon) and exocrine (i.e. production of enzymes to aid digestion and subsequent nutrient absorption) functions are critical for nutritional metabolism and chronic diseases including diabetes. A previous systematic review of effects of severe acute malnutrition on pancreatic exocrine function in children concluded that there was evidence of association but could not determine causality(Reference Bartels, van den Brink and Bandsma6). Diabetes mellitus (DM) is one of the most common non-communicable diseases worldwide and is rapidly increasing, particularly in LMIC(7).While it is established that overweight and obesity in adult life increase the risk of type 2 DM(Reference Leitner, Fruhbeck and Yumuk8), the contribution of prior malnutrition to the aetiology of DM and its potential interaction with later overweight across the global context remains unclear.

In 1965, a WHO Expert Committee reported that ‘the evidence that undernutrition protects adult populations from diabetes seems unassailable’(9). In 1980, they reported that ‘in some societies, malnutrition is probably a major determinant of diabetes’(10). In 1985, malnutrition-related DM was included as a classification category of DM divided into two subtypes, protein deficiency pancreatic diabetes and fibrocalculous pancreatic diabetes, both commonly reported in tropical countries and usually associated with a history of undernutrition(11). This classification has since been dropped and the literature is inconsistent in the terms and diagnostic criteria used for these atypical forms of diabetes. As well as the above classifications, other commonly used terms have included ‘tropical diabetes’, ‘malnutrition-associated diabetes’ and ‘African diabetes’. A recent systematic review concluded that, based on currently limited data, two main phenotypes of atypical diabetes emerge, differing in usual age of onset and in the requirement for lifelong insulin but both occurring in younger ages than is typical for type 2 DM and in underweight individuals or normal weight/modestly overweight individuals; both phenotypes have some features similar to type 1 DM(Reference Bavuma, Sahabandu and Musafiri12). Previous reviews have assessed famine, or malnutrition in a particular age group, and either exocrine function or diabetes as an outcome of endocrine dysfunction but not detailed markers of glucose metabolism(Reference Bartels, van den Brink and Bandsma6,Reference Grey, Gonzales and Abera13) . The present study includes detailed glucose metabolism markers and diabetes as well as exocrine pancreas functions in relation to the less studied, postnatal period of exposure to acute malnutrition, not limited to the postnatal period but including childhood and adulthood and from infection-associated malnutrition. Excluding this, most common type of malnutrition exposure could lead to underestimating the impact on populations which might underlie the large increase in diabetes in populations still experiencing a high burden of infectious diseases. Finally, the decision to include anorexia nervosa (AN) as another exposure was to allow the comparison with malnutrition in which diet restriction, rather than infection, has the main causal role.

This systematic review aims to describe the available evidence to determine if severe acute postnatal malnutrition causes persisting changes in pancreatic endocrine and exocrine function and later increased risk of DM.

Methods

Search strategy

An electronic literature search was performed on PubMed, Web of Science and Google Scholar to identify studies published in English from the earliest available date to 1 February 2022. Detailed search terms are shown in Supplementary Data 1. Studies were eligible for inclusion if they reported human pancreatic function in relation to exposure to postnatal malnutrition identified through clinical or anthropometric methods in hospitals, clinics or communities, famine or eating disorders. Studies were excluded if written in languages other than English, if the full text was unavailable, if study participants had no prior or current malnutrition exposure or only prenatal malnutrition exposure or if stunting (chronic malnutrition) without wasting (acute malnutrition) was the exposure. We included cross-sectional studies to investigate acute associations between malnutrition and pancreas function and trials, cohort studies or retrospective case–control studies to investigate longer term outcomes. Case series and case reports and studies with ≤ 10 participants were excluded from the review owing to the high potential for bias. Studies describing abnormal pancreatic function, for example, due to cystic fibrosis, leading to malnutrition were also excluded. Cancer studies were excluded since, although many cancers may result in malnutrition, the added metabolic complications of cancers and their treatment would make it difficult to determine the effects of malnutrition itself. However, we did include studies of malnutrition secondary to serious infections such as HIV or tuberculosis with the rationale that infections are virtually always part of severe malnutrition, including classical malnutrition in young children.

Duplicates were identified and removed, and the titles and abstracts were reviewed to determine possible eligibility by a single reviewer (FF). Additional studies were identified by manually searching the reference lists of included papers and previous reviews or meta-analyses. The full texts of the relevant articles were obtained and independently reviewed for final selection according to the eligibility criteria by at least two of the authors. Any differences in judgment were discussed with all authors to reach consensus.

Quality assessment

A quality assessment checklist was developed based upon the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE)(Reference von Elm, Altman and Egger14) and Consolidating Reporting of Clinical Trials (CONSORT) checklists(Reference Schulz, Altman and Moher15). The quality assessment checklist comprised sixteen items for cross-sectional studies, nineteen items for cohort studies, twenty items for case–control studies and twenty-two items for clinical trials where scores for each question item ranged from 0 to 2. Scores were assigned as follows: ‘0’ for no information/unlikely or not reported/poor or inappropriate description; ‘1’ for partially or possibly reported/satisfactory and ‘2’ meaningfully reported/good. Using these checklists, three authors (FF, SC, and NBS) independently evaluated the included articles. Scores and decisions were then discussed before assigning an overall quality rating of each study with each article’s quality rated as ‘high’ if score ≥ 80 %; ‘medium’ if score 60–79 %; ‘low’ if score < 45–59 % or very low if score < 45 %.

Data extraction

Details of the included studies were extracted into an Excel file under the following headings: first author, year of publication, study design, country, quality category, age when participants were malnourished, number of participants, participant inclusion/exclusion criteria, diagnostic criteria or definition of malnutrition used, pancreatic outcomes assessed, a description of any interventions or treatment/nutritional rehabilitation received, the type, timing and frequency of pancreatic function outcome assessments conducted and the main or most salient results plus a column for further comments.

Results

Articles included and excluded

After the removal of duplicates, 8108 articles were identified. After screening of abstracts, full texts of 259 papers were obtained (Fig. 1). An additional thirty articles meeting the study inclusion criteria were obtained from a manual screening of article reference lists. Of the 289 articles, 221 articles were excluded due to not meeting the inclusion criteria, leaving sixty-eight articles. The list of excluded studies with reasons is provided in Supplementary Data 2.

Fig. 1. A systematic review flow diagram of the number of articles identified and examined at each stage of the review. *Reference lists from identified full-text articles

The included articles represent results from twenty-nine countries and a total of 592 530 participants. Results are presented divided into three tables based on the nature of the malnutrition exposure and then split into exocrine and endocrine outcomes. Table 1 includes studies reporting the association between malnutrition in young children and exocrine (n 13)(Reference Bartels, Bourdon and Potani16Reference Barbezat28), or endocrine (n 19)(Reference Adegbenro, Dada and Olanrewaju29Reference Milner47), pancreatic function either concurrently or after follow-up, most of which was short term. Table 2 includes studies reporting the association between malnutrition in older children or adults, mainly AN patients, and exocrine (n 3)(Reference Tandon, George and Sama48Reference Martinez-Olmos, Peino and Prieto-Tenreiro50) or endocrine (n 15)(Reference Blickle, Reville and Stephan51Reference Filteau, Praygod and Rehman65) pancreatic function. Table 3 includes studies reporting the association between famine exposure in infancy to young adulthood and glucose metabolism or endocrine (n 18)(Reference Finer, Iqbal and Lowe66Reference Zhou, Sheng and Fan83) pancreatic function; there were no papers describing exocrine pancreas function after childhood famine exposure.

Table 1. Association between concurrent/short-term outcome of childhood malnutrition and pancreatic function

FU, follow-up; MN, malnutrition or malnourished; MS, marasmus; KK, kwashiorkor; SST, stimulation test with secretin or cholecystokinin; SAM, severe acute malnutrition; RCT, randomised controlled trial; WAZ; weight-for-age Z score; FBG, fasting blood or plasma glucose; FE, faecal elastase-1; WfA, weight-for-age using percentiles; WfH, weight-for-height/length using percentiles; HbA1c, glycosylated Hb; IVGTT, intravenous glucose tolerance test; LAZ, length-for-age; MUAC, mid-upper arm circumference; OGTT; oral glucose tolerance test; .

Table 2. Association between late childhood or adult malnutrition and pancreatic function

MN, malnutrition/malnourished; AN, anorexia nervosa; SMN, severe malnutrition; SST, secretin stimulation test; NR, nutrition rehabilitation; IVGTT; intravenous glucose tolerance test; DM, diabetes mellitus; FPG, fasting plasma glucose; IGT, impaired glucose tolerance; OGTT; oral glucose tolerance test; FBG, fasting blood glucose; ICD, International Classification of Diseases.

Table 3. Association between famine experience during childhood and adult endocrine pancreatic function

OGTT; oral glucose tolerance test; DM, diabetes mellitus; FBG, fasting blood glucose; FPG, fasting plasma glucose; RPG, random plasma glucose; HbA1c, glycosylated Hb; HOMA, homeostatic model assessments; HOMA-β, HOMA β cell function; HOMA-IR, HOMA insulin resistance.

Study design and participants characteristics

There were thirty-two cross-sectional studies,(Reference Briars, Thornton and Forrest18,Reference Keni, Jain and Mehra22,Reference Sauniere, Sarles and Attia24,Reference Widodo, Timan and Bardosono27,Reference Adegbenro, Dada and Olanrewaju29,Reference Bowie32,Reference James and Coore34Reference Slone, Taitz and Gilchrist36,Reference Spoelstra, Mari and Mendel39,Reference Cook42,Reference Kajubi43,Reference Tandon, George and Sama48,Reference Blickle, Reville and Stephan51,Reference Wallensteen, Ginsburg and Persson53,Reference Sizonenko, Rabinovitch and Schneider54,Reference Brown, Ward and Surwit57,Reference Casper, Pandey and Jaspan58,Reference Letiexhe, Scheen and Lefebvre60,Reference Finer, Iqbal and Lowe66Reference Li, He and Qi68,Reference Stanner, Bulmer and Andres71,Reference Sun, Zhang and Duan72,Reference Wang, Wang and Han75Reference Zhang, Liu and Wang79,Reference Woo, Leung and Wong81Reference Zhou, Sheng and Fan83) , twenty-seven cohort studies,(Reference Bartels, Meyer and Stehmann17,Reference Danus, Urbina and Valenzuela19Reference El-Hodhod, Nassar and Hetta21,Reference Barbezat28,Reference Becker, Pimstone and Hansen30,Reference Becker, Pimstone and Hansen31,Reference Hadden33,Reference Prinsloo, De Bruin and Kruger37,Reference Becker, Pimstone and Hansen41,Reference Pereyra, Lopez-Arana and Horta46,Reference Milner47,Reference Tandon, Banks and George49,Reference Martinez-Olmos, Peino and Prieto-Tenreiro50,Reference Kumai, Tamai and Fujii52,Reference Fujii, Tamai and Kumai55,Reference Kobayashi, Tamai and Takii56,Reference Ji, Sundquist and Sundquist59,Reference Zuniga-Guajardo, Garfinkel and Zinman61,Reference Smith, Edgar and Pozefsky63Reference Filteau, Praygod and Rehman65,Reference Meng, Lv and Yu69,Reference Portrait, Teeuwiszen and Deeg70,Reference Thurner, Klimek and Szell73,Reference van Abeelen, Elias and Bossuyt74,Reference Lu, Li and Xu80) , of which nineteen were clinical cohorts, mostly comprising short-term follow-up of inpatient malnourished children or adults; three case–control studies(Reference Francis-Emmanuel, Thompson and Barnett44,Reference Gonzalez-Barranco, Rios-Torres and Castillo-Martinez45,Reference Sathiaraj, Gupta and Chutke62) , and six intervention trials(Reference Bartels, Bourdon and Potani16,Reference Mehta, Saini and Singh23,Reference Sauniere and Sarles25,Reference Thompson and Trowell26,Reference Robinson and Seakins38,Reference Becker, Mann and Weinkove40) , not all randomised. Of the total 592 530 participants, most were from the famine studies including one nationwide study with 325 998 participants, mostly non-famine-exposed controls(Reference Thurner, Klimek and Szell73). Most other studies had fewer than 100 participants and addressed malnutrition in young children.

Study quality assessment

Individual studies’ quality scores are shown in Supplementary Data 3. Twelve studies had an overall quality rating considered to be high(Reference Bartels, Bourdon and Potani16,Reference Ji, Sundquist and Sundquist59,Reference Hult, Tornhammar and Ueda67Reference Meng, Lv and Yu69,Reference Sun, Zhang and Duan72Reference Wang, Cheng and Han76,Reference Wang, Li and Han78) , fifteen studies were rated as medium(Reference Spoelstra, Mari and Mendel39,Reference Francis-Emmanuel, Thompson and Barnett44,Reference Gonzalez-Barranco, Rios-Torres and Castillo-Martinez45,Reference Fujii, Tamai and Kumai55,Reference Casper, Pandey and Jaspan58,Reference Sathiaraj, Gupta and Chutke62,Reference Filteau, Praygod and Rehman65,Reference Finer, Iqbal and Lowe66,Reference Portrait, Teeuwiszen and Deeg70,Reference Stanner, Bulmer and Andres71,Reference Wang, Zou and Yang77,Reference Zhang, Liu and Wang79,Reference Lu, Li and Xu80,Reference Zheng, Wang and Ren82,Reference Zhou, Sheng and Fan83) , seventeen studies were rated as low(Reference Bartels, Meyer and Stehmann17,Reference Briars, Thornton and Forrest18,Reference Mehta, Saini and Singh23Reference Sauniere and Sarles25,Reference Widodo, Timan and Bardosono27,Reference Adegbenro, Dada and Olanrewaju29,Reference Becker, Pimstone and Hansen30,Reference Garg, Marwaha and Ganpathy35,Reference Becker, Mann and Weinkove40,Reference Kajubi43,Reference Pereyra, Lopez-Arana and Horta46,Reference Kumai, Tamai and Fujii52,Reference Wallensteen, Ginsburg and Persson53,Reference Brown, Ward and Surwit57,Reference Letiexhe, Scheen and Lefebvre60,Reference Woo, Leung and Wong81) and the remaining twenty-four as very low(Reference Danus, Urbina and Valenzuela19Reference Keni, Jain and Mehra22,Reference Thompson and Trowell26,Reference Barbezat28,Reference Becker, Pimstone and Hansen31Reference James and Coore34,Reference Slone, Taitz and Gilchrist36Reference Robinson and Seakins38,Reference Becker, Pimstone and Hansen41,Reference Cook42,Reference Milner47Reference Blickle, Reville and Stephan51,Reference Sizonenko, Rabinovitch and Schneider54,Reference Kobayashi, Tamai and Takii56,Reference Zuniga-Guajardo, Garfinkel and Zinman61,Reference Smith, Edgar and Pozefsky63,Reference Kanis, Brown and Fitzpatrick64) . The main problems resulting in a poor score were not clearly stated study design, undefined sampling strategy, unclear study inclusion and exclusion criteria, low sample size, unclear or absent statistical methods or investigation of confounders or lack of appropriate control/healthy comparison groups. These problems were mainly found in older studies done at a time of different expectations for study design and presentation but many of these studies appear otherwise carefully conducted and contain valuable information for this review. It should be noted that similar data found in some of these studies is unlikely to be collected in future since the studies used invasive techniques in children which would not be approved by most modern ethics committees.

Definition of the malnutrition exposure

The definition of childhood severe malnutrition has varied over the publication dates of included studies from clinical definitions of kwashiorkor and marasmus, comparison with various different child growth standards, and more recently, the current WHO definition of severe acute malnutrition based on the 2005 growth standards or oedema(84). While there may be minor differences between definitions, we believe these likely reflect broadly the same clinical conditions across time and have therefore considered the definitions of childhood clinical malnutrition together. The more important difference for effects on the pancreas appears to be whether or not the severe acute malnutrition involved oedema, that is, kwashiorkor. Adult malnutrition in the included papers has generally been caused by low BMI and/or a clinical diagnosis of AN. For the studies of long-term consequences of childhood famine exposure, there were no assessments of malnutrition at the time so exposure was defined by date and place of residence at the time.

Definitions of exocrine and endocrine pancreas outcomes

Tests used in the included studies of exocrine pancreas function fit into two main groups. Some earlier work measured enzymes in duodenal juice collected with a catheter, both basally and after stimulation with secretin or cholecystokinin, whereas recent studies were less invasive and collected only faeces or serum; this makes it hard to compare results. Studies using catheters and collecting duodenal fluid before and after simulation measured various enzymes, including amylase, lipase, phospholipase, trypsin and chymotrypsin, as well as bicarbonate and electrolytes(Reference Danus, Urbina and Valenzuela19,Reference Keni, Jain and Mehra22Reference Thompson and Trowell26,Reference Barbezat28,Reference Tandon, George and Sama48,Reference Tandon, Banks and George49) . Recent studies assessed faecal elastase, which is low in pancreatic insufficiency(Reference Bartels, Bourdon and Potani16,Reference Bartels, Meyer and Stehmann17,Reference Widodo, Timan and Bardosono27,Reference Martinez-Olmos, Peino and Prieto-Tenreiro50) , or blood levels of enzymes such as trypsinogen, amylase or lipase which may be either high or low in pancreatic disorders(Reference Briars, Thornton and Forrest18,Reference Durie, Forstner and Gaskin20,Reference El-Hodhod, Nassar and Hetta21) . One study measured pancreas head size in children using ultrasound(Reference El-Hodhod, Nassar and Hetta21) and another measured d-xylose and triglyceride absorption(Reference Martinez-Olmos, Peino and Prieto-Tenreiro50).

As for exocrine pancreas tests, the older and more recent literature generally use different tests for endocrine function, although this is partly driven by the fact that much of the more recent literature is from post-famine studies which, with their very large sample sizes, use mostly simple tests or diagnoses from clinical databases. In some studies, the main outcome was fasting blood or plasma glucose(Reference Adegbenro, Dada and Olanrewaju29,Reference Robinson and Seakins38,Reference Francis-Emmanuel, Thompson and Barnett44Reference Pereyra, Lopez-Arana and Horta46,Reference Sun, Zhang and Duan72,Reference Wang, Cheng and Han76,Reference Wang, Zou and Yang77,Reference Zhang, Liu and Wang79,Reference Lu, Li and Xu80,Reference Zheng, Wang and Ren82,Reference Zhou, Sheng and Fan83) . One study had only random plasma glucose(Reference Hult, Tornhammar and Ueda67). HbA1c was measured mainly but not exclusively in the large famine studies(Reference Adegbenro, Dada and Olanrewaju29,Reference Filteau, Praygod and Rehman65,Reference Sun, Zhang and Duan72,Reference Wang, Wang and Han75Reference Wang, Li and Han78) . Some of these large studies used previously clinically diagnosed diabetes from national or other large databases(Reference Ji, Sundquist and Sundquist59,Reference Meng, Lv and Yu69,Reference Portrait, Teeuwiszen and Deeg70,Reference Thurner, Klimek and Szell73,Reference van Abeelen, Elias and Bossuyt74,Reference Lu, Li and Xu80Reference Zhou, Sheng and Fan83) . Oral glucose tolerance tests (OGTT)(Reference Becker, Pimstone and Hansen30,Reference Becker, Pimstone and Hansen31,Reference Hadden33,Reference Garg, Marwaha and Ganpathy35,Reference Spoelstra, Mari and Mendel39,Reference Becker, Mann and Weinkove40,Reference Kajubi43Reference Gonzalez-Barranco, Rios-Torres and Castillo-Martinez45,Reference Casper, Pandey and Jaspan58,Reference Kanis, Brown and Fitzpatrick64Reference Finer, Iqbal and Lowe66,Reference Li, He and Qi68,Reference Stanner, Bulmer and Andres71,Reference Lu, Li and Xu80,Reference Zhou, Sheng and Fan83) were frequently conducted as were intravenous glucose tolerance tests (IVGTT)(Reference Becker, Pimstone and Hansen30Reference James and Coore34,Reference Slone, Taitz and Gilchrist36,Reference Prinsloo, De Bruin and Kruger37,Reference Becker, Pimstone and Hansen41,Reference Cook42,Reference Milner47,Reference Blickle, Reville and Stephan51,Reference Letiexhe, Scheen and Lefebvre60,Reference Smith, Edgar and Pozefsky63) . These generally followed similar standard protocols. Some researchers measured insulin as well as glucose in these tests. Researchers rarely used these tolerance tests to diagnose diabetes but were interested in various glucose metabolism indicators calculated from the glucose and insulin levels during the tests, including AUC, insulin : glucose ratios and glucose disappearance rate. Homeostatic model assessment indices were rarely calculated(Reference Pereyra, Lopez-Arana and Horta46,Reference Wang, Wang and Han75) . Several studies investigated glucose metabolism after injection or perfusion with glucagon(Reference Kajubi43,Reference Milner47,Reference Kobayashi, Tamai and Takii56) , insulin(Reference Pereyra, Lopez-Arana and Horta46,Reference Fujii, Tamai and Kumai55) or arginine(Reference Blickle, Reville and Stephan51,Reference Sizonenko, Rabinovitch and Schneider54,Reference Fujii, Tamai and Kumai55) . There were single studies using each of the following methods: a standard meal as the glucose challenge(Reference Brown, Ward and Surwit57), a euglycaemic hyperinsulinaemic clamp method(Reference Zuniga-Guajardo, Garfinkel and Zinman61) and only 24-h C-peptide excretion(Reference Wallensteen, Ginsburg and Persson53).

Exocrine pancreas function during and after malnutrition in children and adults

Most papers addressing exocrine pancreas function were from hospital-based studies of acute malnutrition in young children, at admission, during treatment or at hospital discharge; two papers(Reference Sauniere, Sarles and Attia24,Reference Barbezat28) also included some children longer after discharge (Table 1). Among the seven studies which measured duodenal enzymes, most both before and after pancreas stimulation(Reference Danus, Urbina and Valenzuela19,Reference Keni, Jain and Mehra22Reference Thompson and Trowell26,Reference Barbezat28) , all but one(Reference Keni, Jain and Mehra22) found decreases in several enzymes (amylase, lipase, trypsin, and chymotrypsin). Short-term nutritional therapy in hospital usually increased enzyme levels but not always to levels of well-nourished controls. Discrepancies among studies may be due to small sample sizes, differences in patient populations and the duration and type of nutritional or other therapy.

Three studies(Reference Bartels, Bourdon and Potani16,Reference Bartels, Meyer and Stehmann17,Reference Widodo, Timan and Bardosono27) , two from the same research group, used faecal elastase as the exocrine pancreas marker. The study in Indonesia(Reference Widodo, Timan and Bardosono27), which was concerned mainly with diarrhoea and did not clearly define malnutrition, found no differences in elastase between malnourished children at hospital admission and well-nourished children. The studies in Malawi(Reference Bartels, Bourdon and Potani16,Reference Bartels, Meyer and Stehmann17) included no well-nourished children but investigated changes over time during therapy among malnourished children; children with oedematous malnutrition had lower faecal elastase than those with non-oedematous and generally did not recover within a month of nutritional therapy. In all these studies, there is a concern that diarrhoea, which is common among children hospitalised with malnutrition, could interfere with the use of faecal elastase as a marker of pancreas function.

Four studies, all with fairly large sample sizes, measured pancreatic enzymes in blood or serum.(Reference Bartels, Meyer and Stehmann17,Reference Briars, Thornton and Forrest18,Reference Durie, Forstner and Gaskin20,Reference El-Hodhod, Nassar and Hetta21) . Circulating trypsinogen was higher in children with oedematous compared with non-oedematous malnutrition(Reference Bartels, Meyer and Stehmann17), and in malnourished children than in healthy controls(Reference Durie, Forstner and Gaskin20). In one study, serum trypsinogen was not associated with malnutrition but was increased in children with gastroenteritis(Reference Briars, Thornton and Forrest18). Serum amylase and lipase, as well as pancreas head size, were low in malnourished children at hospital admission compared with healthy controls and increased during treatment(Reference El-Hodhod, Nassar and Hetta21).

There is limited information about exocrine pancreas function during or after malnutrition occurring in adulthood (Table 2). There was no difference in faecal elastase among ten AN patients before and after nutritional recovery; this study also found normal d-xylose and triglyceride absorption(Reference Martinez-Olmos, Peino and Prieto-Tenreiro50). Two papers from the same group in India studied possibly overlapping small numbers of malnourished adults and controls(Reference Tandon, George and Sama48,Reference Tandon, Banks and George49) . Before nutritional therapy, malnourished adults had steatorrhoea and low duodenal juice contents of trypsin and lipase basally and post-stimulation with cholecystokinin (pancreozymin) and secretin; amylase content was low only post-stimulation. After nutritional therapy, lipase and amylase differed little from values in healthy controls both before and after stimulation while trypsin remained low.

Endocrine pancreas function

Studies in young children

This group comprises the bulk of the included papers but only one was scored as medium quality(Reference Spoelstra, Mari and Mendel39) and the rest were rated as low or very low quality. Fasting blood or plasma glucose (not always distinguished in the papers and referred to here as FBG), was generally unaffected by acute malnutrition(Reference Hadden33Reference Garg, Marwaha and Ganpathy35,Reference Prinsloo, De Bruin and Kruger37,Reference Robinson and Seakins38,Reference Milner47) but decreased FBG was also reported(Reference Adegbenro, Dada and Olanrewaju29,Reference Slone, Taitz and Gilchrist36,Reference Pereyra, Lopez-Arana and Horta46) . HbA1c was higher in children with kwashiorkor or marasmus compared with controls and FBG and HbA1c were inversely associated(Reference Adegbenro, Dada and Olanrewaju29). Altered fluid balance, especially among children with oedematous malnutrition, and the more acute time frame represented by FBG than by HbA1c may have contributed to an apparently anomalous negative correlation between FBG and HbA1c.

Slow glucose disappearance rates during OGTT or IVGTT were commonly seen at hospital admission in malnourished children, especially those with kwashiorkor(Reference Bowie32Reference James and Coore34,Reference Prinsloo, De Bruin and Kruger37,Reference Becker, Pimstone and Hansen41) but not always in those with marasmus(Reference Hadden33). One study(Reference Bowie32) suggested that lack of insulin was not the reason for slow glucose disappearance since insulin infusion in four children with kwashiorkor did not increase the glucose disappearance rate. Another study(Reference Hadden33) found that glucose disappearance rate in kwashiorkor patients was negatively correlated with blood fatty acids which suggest a role for insulin resistance. However, a small study which used stable isotopes to investigate glucose metabolism found no evidence for hepatic or peripheral insulin resistance but did note that glucose clearance was positively correlated with plasma albumin(Reference Spoelstra, Mari and Mendel39). Nutritional therapy generally normalised glucose disappearance rate(Reference Hadden33,Reference Prinsloo, De Bruin and Kruger37,Reference Becker, Pimstone and Hansen41) although one study found this was still slow in children 6–12 years post-hospitalisation for kwashiorkor(Reference Cook42).

Fasting plasma insulin in different studies of kwashiorkor or marasmus was variable, likely reflecting variable populations and small sample sizes(Reference Hadden33,Reference Garg, Marwaha and Ganpathy35,Reference Robinson and Seakins38) . Insulin release during an OGTT or IVGTT, measured either as plasma levels or in relation to glucose, was generally low for children admitted to hospital mainly with kwashiorkor but sometimes also with non-oedematous malnutrition(Reference Becker, Pimstone and Hansen30,Reference Becker, Pimstone and Hansen31,Reference James and Coore34,Reference Spoelstra, Mari and Mendel39Reference Becker, Pimstone and Hansen41) , although one study found high peak insulin during an OGTT in malnourished children(Reference Garg, Marwaha and Ganpathy35). Insulin levels increased in the short term with nutritional therapy but were not always restored to normal even months after admission(Reference Becker, Pimstone and Hansen30,Reference Hadden33,Reference James and Coore34,Reference Prinsloo, De Bruin and Kruger37,Reference Robinson and Seakins38) , although the overall patterns of response normalised(Reference Becker, Pimstone and Hansen31). Interestingly, in a series of studies by the same research group with overlapping patient populations(Reference Becker, Pimstone and Hansen30,Reference Becker, Pimstone and Hansen31,Reference Becker, Mann and Weinkove40) , insulin/glucose AUC was more reduced and patterns of response more abnormal compared with controls during an OGTT than in an IVGTT, and a pattern of delayed insulin secretion in malnutrition was common; both these could indicate that part of the impaired insulin response was due to factors in the intestine. One study measured plasma glucagon and found low fasting levels in children admitted to hospital for malnutrition(Reference Robinson and Seakins38).

Five studies investigated endocrine pancreas function using OGTT or IVGTT in participants several years after they were hospitalised for malnutrition in early childhood(Reference Becker, Pimstone and Hansen30,Reference Cook42Reference Gonzalez-Barranco, Rios-Torres and Castillo-Martinez45) . Ten years post-kwashiorkor, there was no difference compared with sibling controls in peak insulin or insulin/glucose AUC in an IVGTT(Reference Becker, Pimstone and Hansen30). There were two small studies from the same malnutrition unit in Uganda of children about 10 years after they recovered from kwashiorkor. One found a slower glucose disposal rate during an IVGTT in recovered malnourished children compared with controls(Reference Cook42). The other study found lower fasting insulin in recovered kwashiorkor patients but normal insulin response in an OGTT and with a glucagon stimulus to elicit maximal insulin release(Reference Kajubi43). More recent studies with larger sample sizes found larger differences in glucose metabolism of malnutrition survivors compared with controls. Jamaican adults who had experienced marasmus in early childhood had lower insulin secretion and poorer glucose tolerance in an OGTT compared with kwashiorkor survivors or not previously malnourished controls(Reference Francis-Emmanuel, Thompson and Barnett44). Among young adult Mexican male survivors of childhood malnutrition, plasma glucose concentration and AUC in an OGTT were higher than in not previously malnourished controls only after controlling for BMI, age and birth weight, whereas plasma insulin was higher both with and without controlling for these variables and the difference between cases and controls was greater in those with higher BMI(Reference Gonzalez-Barranco, Rios-Torres and Castillo-Martinez45). A recent study in 1080 Chilean adults found higher glycaemia at age 22–28 years in those who were wasted or at risk of wasting at 12 months (WLZ score < –2 or < –1), including after adjustment for confounders including birth weight and gestational age. Those who were underweight (WAZ-score < –2) at 12 months had evidence of increased glycaemia in unadjusted but not adjusted analysis but increased insulin sensitivity when assessed using single point insulin sensitivity estimate but not homeostatic model assessment-insulin resistance(Reference Pereyra, Lopez-Arana and Horta46).

Endocrine pancreas function after malnutrition in later life

Of fifteen papers on endocrine pancreas function after malnutrition experienced in later childhood or adulthood, twelve are about AN patients, only one of which included males(Reference Ji, Sundquist and Sundquist59), two are about Indian adults and one is about African adults (Table 2). The quality scores for the majority in this group were classified as low or very low, with the exception of a study in Sweden(Reference Ji, Sundquist and Sundquist59) which utilised a national register with long-term follow-up and was rated as high quality, plus four studies rated as medium quality: one from the USA(Reference Casper, Pandey and Jaspan58), a case–control study in malnourished Indian adults(Reference Sathiaraj, Gupta and Chutke62), a cohort study in African malnourished adults(Reference Filteau, Praygod and Rehman65) and a study in Japanese women with AN before and 5 months after treatment(Reference Fujii, Tamai and Kumai55). When patients were admitted to hospital with AN, there was a fairly consistent finding of abnormal, that is, low or delayed, insulin production during OGTT, IVGTT, arginine or glucagon infusion or after a meal(Reference Blickle, Reville and Stephan51,Reference Kumai, Tamai and Fujii52,Reference Sizonenko, Rabinovitch and Schneider54Reference Kobayashi, Tamai and Takii56,Reference Zuniga-Guajardo, Garfinkel and Zinman61,Reference Kanis, Brown and Fitzpatrick64) . Glucose metabolism during these tests was more variable: there was often poor glucose tolerance, as might be expected from the low insulin production(Reference Blickle, Reville and Stephan51,Reference Kumai, Tamai and Fujii52,Reference Kanis, Brown and Fitzpatrick64) , but others found normal responses(Reference Fujii, Tamai and Kumai55). Plasma glucagon was generally not different between AN patients and controls(Reference Blickle, Reville and Stephan51,Reference Sizonenko, Rabinovitch and Schneider54) although one study found abnormal patterns of glucagon changes during an OGTT(Reference Kumai, Tamai and Fujii52), and another found low glucagon after insulin-induced hypoglycaemia but not after arginine infusion(Reference Fujii, Tamai and Kumai55). One study found that 24-h urinary excretion of C-peptide did not differ between AN patients and controls(Reference Wallensteen, Ginsburg and Persson53).

Several studies examined AN patients after weight recovery either just before discharge from care or several years later. Not all studies included controls so it is difficult to determine whether normal pancreas endocrine function was achieved following weight regain. Insulin production and glucose tolerance often improved compared with admission results by the time, usually after several months, AN patients had gained sufficient weight to be discharged(Reference Zuniga-Guajardo, Garfinkel and Zinman61,Reference Kanis, Brown and Fitzpatrick64) , but did not always reach normal levels(Reference Kumai, Tamai and Fujii52,Reference Kobayashi, Tamai and Takii56) . A study of AN patients who had recovered weight, but which provided no information on time since diagnosis, found continued impairments in insulin production but heightened insulin sensitivity resulting in similar glucose responses following a test meal(Reference Brown, Ward and Surwit57). Insulin production remained low and glucose tolerance impaired 8–10 years after AN diagnosis in those who remained low weight but not in those who had achieved normal weight(Reference Casper, Pandey and Jaspan58). The incidence of diabetes diagnoses on a Swedish national register was lower among former AN patients than among the general population but not different from sibling controls; the low incidence among those with prior AN may have been related to their very low incidence of overweight as adults but the study was not designed to control for this(Reference Ji, Sundquist and Sundquist59).

In a study of malnourished Indian adults, in which malnutrition duration and severity were not well defined and there were no well-nourished controls, insulin increase was slow but prolonged in an IVGTT, glucose disposal rate was low and both glucose and insulin responses to arginine infusion were blunted; all responses improved after 2–4 months of nutritional therapy(Reference Smith, Edgar and Pozefsky63). A case–control study of tropical pancreatitis in Indian adults found that 13·5 % of the patients had diabetes, based on fasting and postprandial blood glucose levels, and that weight loss appeared a consequence, not a cause, of the impaired pancreas function(Reference Sathiaraj, Gupta and Chutke62). A cohort study in African adults reported that malnutrition associated mainly with HIV or tuberculosis infection 7–12 years previously was later associated with lower insulin levels in an OGTT in men but not in women(Reference Filteau, Praygod and Rehman65).

Studies in adults exposed to famine in childhood

The famine follow-up studies (Table 3) represent the largest amount of information on long-term outcomes of childhood malnutrition, with by far the largest sample sizes, with generally robust statistics, and when participants were in middle age when diabetes is more common than at younger ages. The famine studies were the majority of studies rated good or medium in the quality assessments. The drawback of the famine studies is that the diagnosis of prior malnutrition is based on date and place of birth so it cannot generally account for local differences in famine exposure or individual or family response to famine, although one study asked participants what they recalled of their famine experience(Reference van Abeelen, Elias and Bossuyt74,Reference Woo, Leung and Wong81) . Another concern is that, particularly in the Chinese famine of 1959–1961 which was prolonged and had high mortality, there is likely to be a survivor bias, and this may have had a sex difference, that is, boys may have had higher mortality than girls(Reference Sun, Zhang and Duan72,Reference Wang, Li and Han78,Reference Lu, Li and Xu80Reference Zhou, Sheng and Fan83) .

Eleven of the eighteen included studies were from China, were done by different research teams and together included data from six representative cohorts (one with two publications from the same group with different purposes(Reference Wang, Wang and Han75,Reference Wang, Cheng and Han76) and another one with two publications by different research groups(Reference Sun, Zhang and Duan72,Reference Wang, Zou and Yang77) ). Methods were similar in that famine exposure was determined by birth location and date with respect to the 1959–1961 famine. Most studies also examined fetal famine exposure which is not the concern here. There were differences among studies regarding the sex and postnatal age for which famine exposure carried the greatest risk of hyperglycaemia (assessed by fasting blood glucose and/or HbA1c) or diabetes: all ages from early to late childhood(Reference Wang, Wang and Han75,Reference Wang, Cheng and Han76,Reference Lu, Li and Xu80,Reference Zheng, Wang and Ren82,Reference Zhou, Sheng and Fan83) , all ages but only in women(Reference Sun, Zhang and Duan72,Reference Wang, Li and Han78) , early childhood in women only(Reference Zhang, Liu and Wang79), infancy only(Reference Wang, Zou and Yang77) or late childhood only(Reference Li, He and Qi68,Reference Woo, Leung and Wong81) . Although both men and women were at increased risk of high fasting plasma glucose or HbA1c, if exposed prenatally, β-cell function, indicated by homeostatic model assessment-β, seemed to be the major problem in men, whereas it was insulin resistance, indicated by homeostatic model assessment-insulin resistance, in women(Reference Wang, Wang and Han75). Women exposed to famine at any stage of childhood had an increased prevalence of hyperglycaemia but not of diabetes, whereas men in the study had no difference in hyperglycaemia but lower prevalence of diabetes(Reference Sun, Zhang and Duan72). In another study that examined sex differences, this was only observed for risk of composite metabolic syndrome, with similar risks among men and women for hyperglycaemia(Reference Zheng, Wang and Ren82). There appears to be an interaction between famine exposure and diet or BMI at the time of glucose assessment: being overweight or currently eating a Western style rather than traditional Chinese diet increased the risk of hyperglycaemia or diabetes after childhood famine exposure(Reference Li, He and Qi68,Reference Wang, Zou and Yang77,Reference Zhou, Sheng and Fan83) . One cohort study investigated the incidence of clinically diagnosed diabetes over about 7 years in middle age(Reference Meng, Lv and Yu69). The incidence was increased among those exposed to famine in utero but not those exposed in childhood and was aggravated by adult abdominal obesity; however, about three times as many cases of prevalent diabetes were excluded from the study as were found to have incident diabetes so it is difficult to determine the overall effect of famine exposure.

The Dutch famine of 1944–1945 has been greatly studied for long-term effects of in utero exposure but less so for postnatal exposure. Famine exposure during adolescence, and to a borderline extent earlier in childhood, increased risk of a later diabetes diagnosis in women but not in men(Reference Portrait, Teeuwiszen and Deeg70). A study which included only women(Reference van Abeelen, Elias and Bossuyt74) found an increased risk of later diabetes by self-report or clinical diagnosis if exposed to famine at any time during childhood and the risk was increased if women reported their famine exposure as severe v. moderate.

Famines in Bangladesh, Hong Kong (on Chinese population), Nigeria, Russia and Austria are represented by one paper each. Early childhood famine exposure in Bangladesh did not affect fasting glucose or glucose response in an OGTT(Reference Finer, Iqbal and Lowe66). In Nigeria, childhood famine exposure had no effect on random blood glucose; unfortunately, the study’s recruitment method precluded use of other tests of glucose metabolism(Reference Hult, Tornhammar and Ueda67). In Hong Kong, self-reported childhood famine exposure was not associated with DM risk(Reference Woo, Leung and Wong81). Childhood famine in Russia was not associated with glucose, insulin, proinsulin or C-peptide in adulthood(Reference Stanner, Bulmer and Andres71). Analysis of a large Austrian national database which included people of a wide age range covering fetal or childhood exposure to several 20th century famines found clear evidence of increased risk of fetal famine exposure but not of childhood exposure(Reference Thurner, Klimek and Szell73). It is unclear why these studies from other countries differ from the general findings of ongoing impaired endocrine pancreas function seen in the Chinese and Dutch famine studies, but differences in famine experience and mortality and in later environment and diet could be important.

Discussion

There is considerably more research on how postnatal malnutrition affects endocrine than exocrine pancreas function. This likely reflects the high prevalence of diabetes globally and its serious health consequences but is in part because there are fewer non-invasive tests of exocrine than endocrine pancreas function available. Some earlier work on exocrine pancreas function used catheters to collect duodenal juice, but such tests are unlikely now to be considered ethically justified for research and the earlier work was of generally poor quality due to low participant numbers, inadequate statistics and consideration of confounding and high risk of selection bias.

Overall, while there are differences among studies of exocrine pancreas function, it seems that secretion of many pancreatic enzymes is reduced in acute childhood malnutrition. The several papers reporting steatorrhoea suggest that this reduced enzyme secretion may have important functional consequences which, through impaired nutrient absorption, could have contributed to the malnutrition in the first place and would very likely exacerbate it. In most cases, nutritional therapy improved enzyme secretion although not always to control levels, possibly because of varying durations and quality of the therapy. One trial which investigated adding enzyme therapy to nutrition(Reference Bartels, Bourdon and Potani16) found no additional benefits; this was a recent study using current WHO nutritional therapy guidelines which likely provide better nutritional support than was available in earlier studies. Our results are consistent with a previous review(Reference Bartels, van den Brink and Bandsma6) which found an association between malnutrition and decreased exocrine pancreas function but could not determine causality.

Regarding endocrine pancreas function, there seem to be prolonged impairments in insulin production among people severely malnourished in childhood or adulthood but these are most profound in people who remain malnourished(Reference Pereyra, Lopez-Arana and Horta46,Reference Milner47) . Adults in LMIC recruited when malnourished may have been so through much of their lives(Reference Tandon, George and Sama48,Reference Tandon, Banks and George49) and long-term impairments in AN patients are greatest in those who remain malnourished(Reference Fujii, Tamai and Kumai55,Reference Brown, Ward and Surwit57) . It would be interesting to investigate insulin in people in LMIC of previously good adult nutritional status who first became malnourished in adulthood. However, adult-onset malnutrition often follows serious infections, for example, with HIV or tuberculosis, or cancers so these factors confound the situation. AN remains the most common cause of severe malnutrition resulting mainly from low dietary intake. Since there appear similarities between observations in AN patients, people exposed to famine in childhood(Reference van Abeelen, Elias and Bossuyt74,Reference Wang, Li and Han78) and adults in LMIC, this suggests that it is malnutrition itself, rather than only the accompanying infections, environmental enteropathy and other aspects of living in poverty, that influence pancreatic insulin production(Reference Fujii, Tamai and Kumai55,Reference Kanis, Brown and Fitzpatrick64,Reference Filteau, Praygod and Rehman65,Reference Portrait, Teeuwiszen and Deeg70,Reference van Abeelen, Elias and Bossuyt74) . Furthermore, since AN normally occurs in people who were previously adequately nourished in high-income countries, the results from AN patients suggest that the direction of causality is from malnutrition to impaired pancreas function, although the opposite direction of causality, with pancreas disease causing malnutrition, may also contribute(Reference Sathiaraj, Gupta and Chutke62).

The mechanisms whereby malnutrition may result in long-term effects on the pancreas are unclear and the studies included in this review provide little information, in part because the more recent and high-quality studies have been mainly large ones investigating the epidemiology of glucose metabolism in famine survivors. Some studies in India have investigated pancreas calcification as the mechanism of the impaired function; such reports contributed to the earlier WHO classification of fibrocalculus pancreatic diabetes(11) but most such studies in the present review were excluded because the main exposure was not prior nutritional status. Environmental enteropathy, which is common in low-income countries and often associated with malnutrition(Reference Prendergast and Kelly85), may have contributed to impaired glucose tolerance in studies of acute malnutrition. Evidence for this comes from studies showing delayed insulin responses or larger effects on the insulin response to OGTT than to IVGTT which bypasses the gut. Possible mechanisms of intestinal epithelial involvement include delayed or reduced glucose absorption(Reference Bandsma, Spoelstra and Mari86) during an OGTT and reduced insulin production because of low incretin production by enterocytes(Reference Rehfeld87).

Most abnormalities in endocrine pancreas function of severely malnourished people seem to improve in the short term with the treatment of the malnutrition; recovery of exocrine pancreas functions after malnutrition has been less studied. There is limited information about long-term pancreas function outside the famine studies. Several of those studies suggest early insults may interact with later diet and illness(Reference Li, He and Qi68,Reference Wang, Zou and Yang77) .This is in keeping with the capacity load model of chronic disease(Reference Wells88) in which damage to a physiological capacity, for example, pancreas functions, earlier in life is most likely to result in health problems if in later life there is a greater load on the system, for example, due to overweight or consumption of a diet high in sugar. Differing prevalence of adult obesity in men and women, in addition to potential sex differences in survival from malnutrition, may contribute to the variable sex differences seen in some of the famine follow-up studies.

Strengths and limitations of the review

A strength of the review is that it included a large number of studies from many countries of varying income levels and with multiple study designs and participant characteristics. The overall similarity in results from very different studies, that is, clinical malnutrition in young children, AN in older children and adults and follow-up of famine studies, lends credence to the findings. At least two of the authors reviewed all the included studies. The review has limitations resulting from the heterogeneity of data from varying methodologies, settings and populations enrolled which also precluded being able to conduct any meaningful meta-analyses. Many of the included studies were of poor quality with small sample sizes, poorly defined populations and unclear statistics. We did not analyse the findings of only good quality studies separately since this would have excluded too many that provided data not available elsewhere. Many of the early studies were conducted to define the aetiology and biology of kwashiorkor v. marasmus so we were not addressing our interests specifically. Similarly, much research on AN was not specifically investigating pancreas function. The techniques used in older compared with newer studies differed and were not always validated, so results are hard to compare. Authors of some of the famine studies were interested in prenatal famine exposure, so they included postnatal exposure as a control for that. The absence of an original aim to investigate postnatal malnutrition and pancreas function could have meant that, even if the study contained data relevant to our search, the title and abstract might not have mentioned it so it would have been missed at the first level of the search; this may explain why a large proportion of the included studies were actually located from the reference lists of other articles found. In addition, we did not include studies where the population was selected based on diabetes because this could have resulted in bias in relation to our aims; for example, studies looking at malnutrition as one of many risk factors for diabetes in a population may have included it in the abstract only if the association was statistically significant, for example, Fekadu et al. (Reference Fekadu, Yigzaw and Alemu89)

Conclusion

Much of the world is currently facing a double burden of under- and over-nutrition in which there is an increasing prevalence of overweight, diabetes and other chronic diseases but an ongoing high prevalence of malnutrition, both in young children and in older individuals with severe infections. There is a need for a better understanding of how these conditions interact in order to improve prevention and treatment of chronic conditions. This review suggests that malnutrition at any postnatal age can have both acute and long-term adverse effects on pancreas function so that diabetes treatments should consider insulin production as well as insulin resistance. Currently, the common first-line pharmacological treatment for diabetes in many settings, including low-income ones where detailed metabolic investigations are often not possible, is metformin which acts primarily on insulin resistance; however, it may not be the best treatment in populations where low insulin production is a major concern(Reference Kibirige, Lumu and Jones90). The similarity of findings from very different populations, including children living in poor environments, adults with malnutrition secondary to severe infections, AN patients and famine survivors, suggests that it is malnutrition itself which can result in impaired pancreas functions. If infection-mediated malnutrition has life-long impacts on diabetes risk, this provides added impetus to prevent and treat this malnutrition beyond achieving favourable outcomes of the original infection, for example, tuberculosis or HIV. More well-designed research with clearly defined populations, adequate sample sizes, consideration of the sexes separately and using robust current techniques to determine the contribution of low insulin production or increased insulin resistance, is needed in order to understand both the epidemiology and mechanisms of interactions between malnutrition and pancreas functions.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114522001404

Acknowledgements

This review was supported by salary contributions from the UK Medical Research Council, grant MR/T006285/1 and from core-funding from Nagasaki University awarded to SEC. The funders had no role in any aspect of the work.

F. F. conducted the main literature search, contributed to data extraction and quality assessment and drafted tables and the initial text; S. F. provided the initial idea, contributed to data extraction and drafted the text; N. B. S. and S. G-M. contributed to data extraction and quality assessment; S. E. C. contributed to data extraction, quality assessment and manuscript writing. All authors approved the final version.

There are no conflicts of interest.

Footnotes

Shared first authors.

References

Ashworth, A, Khanum, S, Jackson, A, et al. (2003) Guidelines for the Inpatient Treatment of Severely Malnourished Children. Geneva: WHO.Google Scholar
Dalvi, PS, Yang, S, Swain, N, et al. (2018) Long-term metabolic effects of malnutrition: Liver steatosis and insulin resistance following early-life protein restriction. PLOS ONE 13, e0199916.CrossRefGoogle ScholarPubMed
Ibrahim, MK, Zambruni, M, Melby, CL, et al. (2017) Impact of childhood malnutrition on host defense and infection. Clin Microbiol Rev 30, 919971.CrossRefGoogle ScholarPubMed
Calkins, K & Devaskar, SU (2011) Fetal origins of adult disease. Curr Probl Pediatr Adolesc Health Care 41, 158176.CrossRefGoogle ScholarPubMed
Dolenšek, J, Pohorec, V, Rupnik, MS, et al. (2017) Pancreas Physiology. Challenges in Pancreatic Pathology. Rijeka, Croatia: IntechOpen.Google Scholar
Bartels, RH, van den Brink, DA, Bandsma, RH, et al. (2018) The relation between malnutrition and the exocrine pancreas: a systematic review. J Pediatr Gastroenterol Nutr 66, 193203.CrossRefGoogle ScholarPubMed
World health organization (2020) Diabetes. Geneva: WHO.Google Scholar
Leitner, DR, Fruhbeck, G, Yumuk, V, et al. (2017) Obesity and type 2 diabetes: two diseases with a need for combined treatment strategies – EASO can lead the way. Obes Facts 10, 483492.CrossRefGoogle ScholarPubMed
World Health Organization (1965) Diabetes Mellitus: Report of a WHO Expert Committee. Geneva: WHO.Google Scholar
World Health Organization (1980) WHO Expert Committee on Diabetes Mellitus. Geneva: WHO.Google Scholar
World Health Organization Study Group on Diabetes Mellitus (1985) Diabetes Mellitus: Report of a WHO Study Group. Geneva: WHO.Google Scholar
Bavuma, C, Sahabandu, D, Musafiri, S, et al. (2019) Atypical forms of diabetes mellitus in Africans and other non-European ethnic populations in low- and middle-income countries: a systematic literature review. J Glob Health 9, 020401.CrossRefGoogle ScholarPubMed
Grey, K, Gonzales, GB, Abera, M, et al. (2021) Severe malnutrition or famine exposure in childhood and cardiometabolic non-communicable disease later in life: a systematic review. BMJ Glob Health 6, e003161.CrossRefGoogle ScholarPubMed
von Elm, E, Altman, DG, Egger, M, et al. (2007) The Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) Statement: guidelines for reporting observational studies. Bull World Health Org 85, 867872.CrossRefGoogle ScholarPubMed
Schulz, KF, Altman, DG, Moher, D, et al. (2010) CONSORT 2010 Statement: updated guidelines for reporting parallel group randomised trials. BMJ 340, c332.CrossRefGoogle ScholarPubMed
Bartels, RH, Bourdon, C, Potani, I, et al. (2017) Pancreatic enzyme replacement therapy in children with severe acute malnutrition: a randomized controlled trial. J Pediatr 190, 8592.e82.Google ScholarPubMed
Bartels, RH, Meyer, SL, Stehmann, TA, et al. (2016) Both exocrine pancreatic insufficiency and signs of pancreatic inflammation are prevalent in children with complicated severe acute malnutrition: an observational study. J Pediatr 174, 165170.CrossRefGoogle ScholarPubMed
Briars, GL, Thornton, SJ, Forrest, Y, et al. (1998) Malnutrition, gastroenteritis and trypsinogen concentration in hospitalised Aboriginal children. J Paediatr Child Health 34, 6973.CrossRefGoogle ScholarPubMed
Danus, O, Urbina, AM, Valenzuela, I, et al. (1970) The effect of refeeding on pancreatic exocrine function in marasmic infants. J Pediatr 77, 334337.CrossRefGoogle ScholarPubMed
Durie, PR, Forstner, GG, Gaskin, KJ, et al. (1985) Elevated serum immunoreactive pancreatic cationic trypsinogen in acute malnutrition: evidence of pancreatic damage. J Pediatr 106, 233238.CrossRefGoogle ScholarPubMed
El-Hodhod, MA, Nassar, MF, Hetta, OA, et al. (2005) Pancreatic size in protein energy malnutrition: a predictor of nutritional recovery. Eur J Clin Nutr 59, 467473.CrossRefGoogle ScholarPubMed
Keni, S, Jain, MK, Mehra, R, et al. (1995) Impaired pancreatic bicarbonate secretion in chronic malnutrition. Indian Pediatr 32, 323329.Google ScholarPubMed
Mehta, HC, Saini, AS, Singh, H, et al. (1984) Pancreatic functions in marasmic children: effect of dietary therapy. Indian Pediatr 21, 149153.Google ScholarPubMed
Sauniere, JF, Sarles, H, Attia, Y, et al. (1986) Exocrine pancreatic function of children from the Ivory Coast compared to French children. Effect of kwashiorkor. Dig Dis Sci 31, 481486.CrossRefGoogle ScholarPubMed
Sauniere, JF & Sarles, H (1988) Exocrine pancreatic function and protein-calorie malnutrition in Dakar and Abidjan (West Africa): silent pancreatic insufficiency. Am J Clin Nutr 48, 12331238.CrossRefGoogle ScholarPubMed
Thompson, MD & Trowell, HC (1952) Pancreatic enzyme activity in duodenal contents of children with a type of kwashiorkor. Lancet 1, 10311035.CrossRefGoogle ScholarPubMed
Widodo, AD, Timan, IS, Bardosono, S, et al. (2016) Pancreatic exocrine insufficiency in malnourished children and those with persistent diarrhoeae. Asia Pac J Clin Nutr 25, S57S61.Google ScholarPubMed
Barbezat, GO (1967) The exocrine pancreas and protein-calorie malnutrition. S Afr Med J 41, 84.Google ScholarPubMed
Adegbenro, SA, Dada, OA, Olanrewaju, DM, et al. (1991) Glycosylated haemoglobin levels in children with protein-energy malnutrition. Ann Trop Paediatr 11, 337341.CrossRefGoogle ScholarPubMed
Becker, DJ, Pimstone, BL, Hansen, JD, et al. (1971) Insulin secretion in protein-calorie malnutrition. I. Quantitative abnormalities and response to treatment. Diabetes 20, 542551.CrossRefGoogle ScholarPubMed
Becker, DJ, Pimstone, BL, Hansen, JD, et al. (1972) Patterns of insulin response to glucose in protein-calorie malnutrition. Am J Clin Nutr 25, 499505.CrossRefGoogle ScholarPubMed
Bowie, MD (1964) Intravenous glucose tolerance in Kwashiorkor and Marasmus. S Afr Med J 38, 328329.Google ScholarPubMed
Hadden, DR (1967) Glucose, free fatty acid, and insulin interrelations in kwashiorkor and marasmus. Lancet 2, 589592.CrossRefGoogle ScholarPubMed
James, WP & Coore, HG (1970) Persistent impairment of insulin secretion and glucose tolerance after malnutrition. Am J Clin Nutr 23, 386389.CrossRefGoogle ScholarPubMed
Garg, SK, Marwaha, RK, Ganpathy, V, et al. (1989) Serum growth hormone, insulin and blood sugar responses to oral glucose in protein energy malnutrition. Trop Geogr Med 41, 913.Google ScholarPubMed
Slone, D, Taitz, LS & Gilchrist, GS (1961) Aspects of carbohydrate metabolism in Kwashiorkor. Br Med J 1, 3234.CrossRefGoogle ScholarPubMed
Prinsloo, JG, De Bruin, EJ & Kruger, H (1971) Comparison of intravenous glucose tolerance tests and serum insulin levels in kwashiorkor and pellagra. Arch Dis Child 46, 795800.CrossRefGoogle ScholarPubMed
Robinson, HM & Seakins, A (1982) Fasting pancreatic glucagon in Jamaican children during malnutrition and subsequent recovery. Pediatr Res 16, 10111015.CrossRefGoogle ScholarPubMed
Spoelstra, MN, Mari, A, Mendel, M, et al. (2012) Kwashiorkor and Marasmus are both associated with impaired glucose clearance related to pancreatic beta-cell dysfunction. Metabolism 61, 12241230.CrossRefGoogle ScholarPubMed
Becker, DJ, Mann, MD, Weinkove, E, et al. (1975) Early insulin release and its response to potassium supplementation in protein-calorie malnutrition. Diabetologia 11, 237239.CrossRefGoogle ScholarPubMed
Becker, DJ, Pimstone, BL & Hansen, JDL (1975) The relation between insulin secretion, glucose tolerance, growth hormone, and serum proteins in proteincalorie malnutrition. Pediatr Res 9, 3539.CrossRefGoogle Scholar
Cook, GC (1967) Glucose tolerance after kwashiorkor. Nature 215, 12951296.CrossRefGoogle ScholarPubMed
Kajubi, SK (1972) The endocrine pancreas after kwashiorkor. Am J Clin Nutr 25, 11401142.CrossRefGoogle ScholarPubMed
Francis-Emmanuel, PM, Thompson, DS, Barnett, AT, et al. (2014) Glucose metabolism in adult survivors of severe acute malnutrition. J Clin Endocrinol Metab 99, 22332240.CrossRefGoogle ScholarPubMed
Gonzalez-Barranco, J, Rios-Torres, JM, Castillo-Martinez, L, et al. (2003) Effect of malnutrition during the first year of life on adult plasma insulin and glucose tolerance. Metabolism 52, 10051011.CrossRefGoogle ScholarPubMed
Pereyra, I, Lopez-Arana, S & Horta, BL (2021) Undernutrition and suboptimal growth during the first year are associated with glycemia but not with insulin resistance in adulthood. Cad Saude Publica 37, e00120320.CrossRefGoogle Scholar
Milner, RDG (1971) Metabolic and hormonal responses to glucose and glucagon in patients with infantile malnutrition. Pediatric Research 5, 3339.CrossRefGoogle Scholar
Tandon, BN, George, PK, Sama, SK, et al. (1969) Exocrine pancreatic function in protein--calorie malnutrition disease of adults. Am J Clin Nutr 22, 14761482.CrossRefGoogle ScholarPubMed
Tandon, BN, Banks, PA, George, PK, et al. (1970) Recovery of exocrine pancreatic function in adult protein-calorie malnutrition. Gastroenterology 58, 358362.Google ScholarPubMed
Martinez-Olmos, MA, Peino, R, Prieto-Tenreiro, A, et al. (2013) Intestinal absorption and pancreatic function are preserved in anorexia nervosa patients in both a severely malnourished state and after recovery. Eur Eat Disord Rev 21, 247251.CrossRefGoogle ScholarPubMed
Blickle, JF, Reville, P, Stephan, F, et al. (1984) The role of insulin, glucagon and growth hormone in the regulation of plasma glucose and free fatty acid levels in anorexia nervosa. Horm Metab Res 16, 336340.CrossRefGoogle ScholarPubMed
Kumai, M, Tamai, H, Fujii, S, et al. (1988) Glucagon secretion in anorexia nervosa. Am J Clin Nutr 47, 239242.CrossRefGoogle ScholarPubMed
Wallensteen, M, Ginsburg, BE, Persson, B, et al. (1991) Urinary C-peptide excretion in obese and anorectic children. Acta Paediatr Scand 80, 521526.CrossRefGoogle ScholarPubMed
Sizonenko, PC, Rabinovitch, A, Schneider, P, et al. (1975) Plasma growth hormone, insulin, and glucagon responses to arginine infusion in children and adolescents with idiopathic short stature, isolated growth hormone deficiency, panhypopituitarism, and anorexia nervosa. Pediatr Res 9, 733738.CrossRefGoogle ScholarPubMed
Fujii, S, Tamai, H, Kumai, M, et al. (1989) Impaired glucagon secretion to insulin-induced hypoglycemia in anorexia nervosa. Acta Endocrinol 120, 610615.Google ScholarPubMed
Kobayashi, N, Tamai, H, Takii, M, et al. (1992) Pancreatic B-cell functioning after intravenous glucagon administration in anorexia nervosa. Acta Psychiatr Scand 85, 610.CrossRefGoogle ScholarPubMed
Brown, NW, Ward, A, Surwit, R, et al. (2003) Evidence for metabolic and endocrine abnormalities in subjects recovered from anorexia nervosa. Metabolism 52, 296302.CrossRefGoogle ScholarPubMed
Casper, RC, Pandey, G, Jaspan, JB, et al. (1988) Eating attitudes and glucose tolerance in anorexia nervosa patients at 8-year followup compared to control subjects. Psychiatry Res 25, 283299.CrossRefGoogle ScholarPubMed
Ji, J, Sundquist, J & Sundquist, K (2016) Association between anorexia nervosa and type 2 diabetes in Sweden: Etiological clue for the primary prevention of type 2 diabetes. Endocr Res 41, 310316.CrossRefGoogle ScholarPubMed
Letiexhe, MR, Scheen, AJ & Lefebvre, PJ (1997) Plasma leptin levels, insulin secretion, clearance and action on glucose metabolism in anorexia nervosa. Eat Weight Disord 2, 7986.CrossRefGoogle ScholarPubMed
Zuniga-Guajardo, S, Garfinkel, PE & Zinman, B (1986) Changes in insulin sensitivity and clearance in anorexia nervosa. Metabolism 35, 10961100.CrossRefGoogle ScholarPubMed
Sathiaraj, E, Gupta, S, Chutke, M, et al. (2010) Malnutrition is not an etiological factor in the development of tropical pancreatitis – a case-control study of southern Indian patients. Trop Gastroenterol 31, 169174.Google Scholar
Smith, SR, Edgar, PJ, Pozefsky, T, et al. (1975) Insulin secretion and glucose tolerance in adults with protein-calorie malnutrition. Metabolism 24, 10731084.CrossRefGoogle ScholarPubMed
Kanis, JA, Brown, P, Fitzpatrick, K, et al. (1974) Anorexia nervosa: a clinical, psychiatric, and laboratory study. I. Clinical and laboratory investigation. Q J Med 43, 321338.Google Scholar
Filteau, S, Praygod, G, Rehman, AM, et al. (2021) Prior undernutrition and insulin production several years later in Tanzanian adults. Am J Clin Nutr 113, 16001608.CrossRefGoogle ScholarPubMed
Finer, S, Iqbal, MS, Lowe, R, et al. (2016) Is famine exposure during developmental life in rural Bangladesh associated with a metabolic and epigenetic signature in young adulthood? A historical cohort study. BMJ Open 6, e011768.CrossRefGoogle ScholarPubMed
Hult, M, Tornhammar, P, Ueda, P, et al. (2010) Hypertension, diabetes and overweight: looming legacies of the Biafran famine. PLOS ONE 5, e13582.CrossRefGoogle ScholarPubMed
Li, Y, He, Y, Qi, L, et al. (2010) Exposure to the Chinese famine in early life and the risk of hyperglycemia and type 2 diabetes in adulthood. Diabetes 59, 24002406.CrossRefGoogle Scholar
Meng, R, Lv, J, Yu, C, et al. (2018) Prenatal famine exposure, adulthood obesity patterns and risk of type 2 diabetes. Int J Epidemiol 47, 399408.CrossRefGoogle ScholarPubMed
Portrait, F, Teeuwiszen, E & Deeg, D (2011) Early life undernutrition and chronic diseases at older ages: the effects of the Dutch famine on cardiovascular diseases and diabetes. Soc Sci Med 73, 711718.CrossRefGoogle ScholarPubMed
Stanner, SA, Bulmer, K, Andres, C, et al. (1997) Does malnutrition in utero determine diabetes and coronary heart disease in adulthood? Results from the Leningrad siege study, a cross sectional study. BMJ 315, 13421348.CrossRefGoogle ScholarPubMed
Sun, Y, Zhang, L, Duan, W, et al. (2018) Association between famine exposure in early life and type 2 diabetes mellitus and hyperglycemia in adulthood: Results from the China Health And Retirement Longitudinal Study (CHARLS). J Diabetes 10, 724733.CrossRefGoogle ScholarPubMed
Thurner, S, Klimek, P, Szell, M, et al. (2013) Quantification of excess risk for diabetes for those born in times of hunger, in an entire population of a nation, across a century. Proc Natl Acad Sci USA 110, 47034707.CrossRefGoogle Scholar
van Abeelen, AF, Elias, SG, Bossuyt, PM, et al. (2012) Famine exposure in the young and the risk of type 2 diabetes in adulthood. Diabetes 61, 22552260.CrossRefGoogle Scholar
Wang, N, Wang, X, Han, B, et al. (2015) Is exposure to famine in childhood and economic development in adulthood associated with diabetes? J Clin Endocrinol Metab 100, 45144523.CrossRefGoogle ScholarPubMed
Wang, N, Cheng, J, Han, B, et al. (2017) Exposure to severe famine in the prenatal or postnatal period and the development of diabetes in adulthood: an observational study. Diabetologia 60, 262269.CrossRefGoogle ScholarPubMed
Wang, Z, Zou, Z, Yang, Z, et al. (2018) The association between fetal-stage exposure to the China famine and risk of diabetes mellitus in adulthood: results from the China health and retirement longitudinal study. BMC Public Health 18, 1205.CrossRefGoogle Scholar
Wang, J, Li, Y, Han, X, et al. (2016) Exposure to the Chinese famine in childhood increases type 2 diabetes risk in adults. J Nutr 146, 22892295.CrossRefGoogle Scholar
Zhang, Y, Liu, X, Wang, M, et al. (2018) Risk of hyperglycemia and diabetes after early-life famine exposure: a cross-sectional survey in Northeastern China. Int J Environ Res Public Health 15, 1125.CrossRefGoogle ScholarPubMed
Lu, J, Li, M, Xu, Y, et al. (2020) Early life famine exposure, ideal cardiovascular health metrics, and risk of incident diabetes: findings from the 4C study. Diabetes Care 43, 19021909.CrossRefGoogle ScholarPubMed
Woo, J, Leung, JC & Wong, SY (2010) Impact of childhood experience of famine on late life health. J Nutr Health Aging 14, 9195.CrossRefGoogle ScholarPubMed
Zheng, X, Wang, Y, Ren, W, et al. (2012) Risk of metabolic syndrome in adults exposed to the great Chinese famine during the fetal life and early childhood. Eur J Clin Nutr 66, 231236.CrossRefGoogle Scholar
Zhou, J, Sheng, J, Fan, Y, et al. (2019) The effect of Chinese famine exposure in early life on dietary patterns and chronic diseases of adults. Public Health Nutr 22, 603613.CrossRefGoogle ScholarPubMed
World Health Organization (2020) Severe Acute Malnutrition. Geneva: WHO.Google Scholar
Prendergast, A & Kelly, P (2012) Enteropathies in the Developing World: Neglected Effects on Global Health. Am J Trop Med Hyg 86, 756763.CrossRefGoogle ScholarPubMed
Bandsma, RH, Spoelstra, MN, Mari, A, et al. (2011) Impaired glucose absorption in children with severe malnutrition. J Pediatr 158, 282287.e281.CrossRefGoogle ScholarPubMed
Rehfeld, JF (2018) The origin and understanding of the incretin concept. Front Endocrinol (Lausanne) 9, 387.CrossRefGoogle ScholarPubMed
Wells, JC (2009) Historical cohort studies and the early origins of disease hypothesis: making sense of the evidence. Proc Nutr Soc 68, 179188.CrossRefGoogle ScholarPubMed
Fekadu, S, Yigzaw, M, Alemu, S, et al. (2010) Insulin-requiring diabetes in Ethiopia: associations with poverty, early undernutrition and anthropometric disproportion. Eur J Clin Nutr 64, 11921198.CrossRefGoogle ScholarPubMed
Kibirige, D, Lumu, W, Jones, AG, et al. (2019) Understanding the manifestation of diabetes in sub Saharan Africa to inform therapeutic approaches and preventive strategies: a narrative review. Clin Diabetes Endocrinol 5, 2.CrossRefGoogle ScholarPubMed
World Health Organization (2009) WHO Child Growth Standards and the Identification of Severe Acute Malnutrition in Infants and Children. Geneva: WHO.Google Scholar
Wellcome Trust (1970) Classification of infantile malnutrition. Lancet 2, 302303.Google Scholar
Figure 0

Fig. 1. A systematic review flow diagram of the number of articles identified and examined at each stage of the review. *Reference lists from identified full-text articles

Figure 1

Table 1. Association between concurrent/short-term outcome of childhood malnutrition and pancreatic function

Figure 2

Table 2. Association between late childhood or adult malnutrition and pancreatic function

Figure 3

Table 3. Association between famine experience during childhood and adult endocrine pancreatic function

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