Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-23T05:43:26.715Z Has data issue: false hasContentIssue false

Management of undernutrition and failure to thrive in children with congenital heart disease in low- and middle-income countries

Published online by Cambridge University Press:  04 December 2017

Andrew C. Argent*
Affiliation:
School of Child and Adolescent Health, University of Cape Town, Cape Town, South Africa Paediatric Intensive Care, Red Cross War Memorial Children’s Hospital, Rondebosch, Cape Town, South Africa
Rakhi Balachandran
Affiliation:
Department of Cardiac Anesthesiology, Pediatric Cardiac Intensive Care, Amrita Vishwa Vidyapeetham, Cochin, Kerala, India
Balu Vaidyanathan
Affiliation:
Amrita Institute of Medical Sciences and Research Centre, Amrita Vishwa Vidyapeetham, Cochin, Kerala, India
Amina Khan
Affiliation:
Heart Lungs & Vascular Service Line, Aga Khan University Hospital, Karachi, Pakistan
R. Krishna Kumar
Affiliation:
Amrita Institute of Medical Sciences and Research Centre, Amrita Vishwa Vidyapeetham, Cochin, Kerala, India
*
Correspondence to: A. C. Argent, Professor, School of Child and Adolescent Health, University of Cape Town and, Medical Director, Pediatric Intensive Care, Red Cross War Memorial Children’s Hospital, Klipfontein Road, Rondebosch, Cape Town 7700, South Africa. Tel: +27 21 658 5369; Fax: +27 21 689 1287; E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Poor growth with underweight for age, decreased length/height for age, and underweight-for-height are all relatively common in children with CHD. The underlying causes of this failure to thrive may be multifactorial, including innate growth potential, severity of cardiac disease, increased energy requirements, decreased nutritional intake, malabsorption, and poor utilisation of absorbed nutrition. These factors are particularly common and severe in low- and middle-income countries.

Although nutrition should be carefully assessed in all patients, failure of growth is not a contraindication to surgical repair, and patients should receive surgical repair where indicated as soon as possible.

Close attention should be paid to nutritional support – primarily enteral feeding, with particular use of breast milk in infancy – in the perioperative period and in the paediatric ICU. This nutritional support requires specific attention and allocation of resources, including appropriately skilled personnel.

Thereafter, it is essential to monitor growth and development and to identify causes for failure to catch-up or grow appropriately.

Type
Original Articles
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
© Cambridge University Press 2017

Many children with CHD are underweight for ageReference Unger, DeKleermaeker, Gidding and Christoffel 1 Reference Ehlers 11 and/or stunted – even at an early age. Being significantly underweight for age and wasted has been associated with higher perioperative morbidity and mortality in children with CHD.Reference Anderson, Beekman and Border 12 In addition, the perioperative period is frequently complicated by difficulties with enteral nutritionReference Leite, Fisberg, Novo, Nogueira and Ueda 10 , Reference Schwalbe-Terilli, Hartman and Nagle 13 and potentially with increased nutritional loss associated with problems such as chylothorax.

There is a significant burden of childhood undernutrition in low- and middle-income countries where some 90% of the children born with CHD across the world live.Reference Tchervenkov, Jacobs and Bernier 14 The co-existence of CHD increases the likelihood and severity of undernutrition, and this adds to challenges for the management of CHD including resource constraints; late presentation and diagnosis; and perioperative infection.Reference Jenkins, Castaneda and Cherian 15 Reference Bernier, Stefanescu, Samoukovic and Tchervenkov 18 The number of children, including infants and newborns being operated for CHD, has recently increased in these regions.Reference Jenkins, Castaneda and Cherian 15

This review seeks to summarise existing evidence on prevalence of undernutrition and CHD and its impact on surgical outcomes with a focus on implications for low- and middle-income countries. An effort has been made to identify specific gaps in knowledge as a basis for future multicentre studies.

Definition of malnutrition in CHD

In the context of CHD, it is important to reach a clear consensus on what is meant by malnutrition. Simple measurements, such as height, weight, skinfold thickness, or mid-upper arm circumference, and their relationships, for example, weight-for-height, have been the basis of most definitions of nutritional status. 19 It is not possible to exclude malnutrition on the grounds of normal anthropometry alone, as there may be children with acute malnutrition who fall within the “normal” ranges for standard anthropometry.Reference Van den Broeck, Meulemans and Eeckels 20 Green Corkins has recently highlighted the importance of a full clinical evaluation – versus simply viewing anthropometry – in the assessment of nutrition status in children.Reference Green Corkins 21

Mehta et al defined malnutrition as “an imbalance between nutrient requirement and intake, resulting in cumulative deficits of energy, protein, or micronutrients that may negatively affect growth, development, and other relevant outcomes”Reference Mehta, Corkins and Lyman 22 (see Fig 1). Ideally, any assessment of nutrition and investigations on the role of nutrition in patient management should include data regarding growth over a period of time: actual dietary intake available (and provided); evidence for malabsorption; evidence of inflammatory processes; and evidence of any underlying disease.Reference Becker, Carney and Corkins 23

Figure 1 An approach to nutrition in the child with failure to grow or to gain weight, from Mehta et al.Reference Mehta, Corkins and Lyman 22

Failure to thrive in children with CHD

The basis of growth failure or underweight in CHD appears to be multifactorial and may differ in aetiology from patient to patient. It includes the underlying cardiac anomaly,Reference Blasquez, Clouzeau and Fayon 24 haemodynamic factors, hypoxaemia, inadequate calorie, or macronutrient intake,Reference Unger, DeKleermaeker, Gidding and Christoffel 1 , Reference Schwalbe-Terilli, Hartman and Nagle 13 , Reference Yahav, Avigad and Frand 25 Reference Nicholson, Clabby, Kanter and Mahle 28 increased energy expenditure relative to intake,Reference Menon and Poskitt 29 Reference Mitchell, Davies, Day, Pollock and Jamieson 31 increased inflammation,Reference Goulart, Schuh, Moraes, Barbiero and Pellanda 32 or associated comorbidities that include gut dysfunction,Reference Yahav, Avigad and Frand 25 , respiratory infections, associated genetic syndromes, and reduced growth potential.Reference Varan, Tokel and Yilmaz 7 , Reference Mehrizi and Drash 33 Reference Matthiesen, Henriksen and Gaynor 37

A study of anthropometric data in children with CHD in India showed that recorded dietary intake was not associated with the probability of being underweight.Reference Vaidyanathan, Nair and Sundaram 6 Another study concluded that there was no reduction in intake in children with CHD relative to normal children, whereas “normal serum prealbumin and albumin in the infants with CHD ruled out protein–calorie malnutrition.”Reference Salzer, Haschke, Wimmer, Heil and Schilling 36 The plasma amino acid profile was normal preoperatively in a group of children with CHD, regardless of anthropometric values.Reference Villares, Leal, Diaz and Gonzalez 38 A study from Latin America of children with CHD showed that anthropometric measures of malnutrition were present in >80% of the children; albumin and prealbumin levels were lower than in normal controls, although transferrin levels were no different; and that failure to thrive was worse in children with pulmonary hypertension.Reference Leite, de Camargo Carvalho and Fisberg 39

In low- and middle-income countries with resource limitations, the prevalence of abnormal preoperative anthropometry is high owing to late presentation, delays in corrective intervention, and frequent hospitalisations related to respiratory infections.Reference Vaidyanathan, Nair and Sundaram 6 , Reference Vaidyanathan, Roth, Rao, Gauvreau, Shivaprakasha and Kumar 16 In a cohort of 100 consecutive infants undergoing ventricular septal defect closure, severe underweight (weight z-score <−3) was observed in 46% of patients.Reference Mehrizi and Drash 33 In a prospective study of 476 consecutive patients undergoing corrective intervention for CHD, Vaidyanathan et al reported z-scores <−2 in 59% (weight), 26.3% (height), and 55.9% (weight/height), respectively; z-scores <−3 were observed in 27.7% (weight), 10.1% (height), and 24.2% (weight/height).Reference Vaidyanathan, Nair and Sundaram 6 Congestive heart failure, older age at correction, and limited growth potential as suggested by lower birth weight for gestation, lower parental anthropometry, and genetic syndromes were identified as predictors of “malnutrition”. The International Quality Improvement Collaborative for Congenital Heart Surgery in low- and middle-income countries uses a registry to collect data from over 50 sites. An analysis of data from 15,049 patients with CHD revealed that >50% of children had weight z-scores of −3 or less and 12% had an emaciated appearance before their surgery.Reference Vaidyanathan, Roth, Rao, Gauvreau, Shivaprakasha and Kumar 16

Although anthropometric measurements in children with CHD are frequently abnormal, classical features of malnutrition such as skin changes, presence of oedema, hair changes, and so on are relatively rare in children with CHD. In the setting of malnutrition in Africa, a discrepancy between clinical signs of acute malnutrition and anthropometryReference Van den Broeck, Meulemans and Eeckels 20 may be an important issue to pursue.

Finally, there is evidence that micronutrient deficiencies may be relatively common in children with CHD.Reference Steier, Lopez and Cooperman 40 This has never been explored in low- and middle-income countries where it is even more likely to be an issue.

Supplementary Table 1 summarises data from publications on nutritional status in CHD from low- and middle-income countries.

Impact of preoperative state on postoperative outcome

Because of their lower protein and energy reserves, infants and newborns may be particularly vulnerable to the hypercatabolic state that is expected following heart surgery,Reference Finnerty, Mabvuure, Ali, Kozar and Herndon 41 , Reference Teixeira-Cintra, Monteiro, Tremeschin, Trevilato, Halperin and Carlotti 42 although hypercatabolism may not follow all paediatric cardiac operations.Reference Mehta, Costello and Bechard 43 This situation is further worsened by comorbidities such as lack of protein:calorie provision or major infections (Fig 1). When the acute phase of metabolic stress resolves, the anabolic phase begins, resulting in somatic growth, with decreasing concentrations of acute-phase reactants, proteins, and total urinary nitrogen values, and with increasing concentrations of visceral proteins.Reference Jones, Pierro, Hammond and Lloyd 44 The timing of transition to the anabolic phase is influenced by the extent of “surgical stress”, associated comorbidities, quality of nutritional support, and a number of other potential factors.

Within that framework, there has been concern that cardiac surgery in underweight children with CHD would be associated with worse outcomes. However, there is very little evidence to support the notion that lower weights are associated with poorer surgical outcomes. In a study published in 1992, Hardin et alReference Hardin, Muskett, Canter, Martin and Spray 45 compared two groups of patients undergoing closure of ventricular septal defects (>4 kg and <4 kg) and found no significant difference in outcomes.

In a study from southern India on 100 consecutive infants undergoing surgical closure of ventricular septal defects, 46% had weight z-scores of −3 or lower, although this did not affect postoperative mortality or morbidity, duration of mechanical ventilation, or length-of-stay in the ICU or hospital.Reference Vaidyanathan, Roth, Rao, Gauvreau, Shivaprakasha and Kumar 16 A more recent prospective study of 1028 infants from the same centre studied the impact of preoperative factors on postoperative outcomes after congenital heart surgery.Reference Reddy, Kappanayil and Balachandran 17 Weight z-scores <−3 and low birth weight (<2.5 kg) did not adversely affect mortality or morbidity. These results reinforce the strategy of early correction of CHDs irrespective of nutritional status. Preoperative optimisation of nutritional status through aggressive feeding is not necessary in most patients, although it may make sense to use this technique if there are ongoing delays in access to surgical repair.

Correction verses palliation

The question of correction versus palliation in a severely undernourished child with CHD is likely to be dictated by several factors that include the specific defect, the experience and expertise of the surgical and intensive care teams, and associated comorbidities. Relatively simple CHD that can be corrected through a single operation, such as a ventricular septal defect, should be closed surgically. A study in South Africa demonstrated that when the realities of a staged approach using pulmonary artery banding – including loss to follow-up, delays in definitive procedures, the challenges of two surgical procedures in a context with limited surgical time, and so on – were taken into account, mortality after a staged approach using pulmonary artery banding was higher than primary surgical closure of the ventricular septal defect.Reference Brooks, Geldenhuys, Zuhlke, Human and Zilla 46 Nonetheless, there are clearly situations where pulmonary artery banding may be a useful stage en route to full correction.

Management of undernutrition

Cardiac teams in low- and middle-income countries are frequently faced with children with CHD who are underweight, thin, and stunted. The first response should be to regard that as further evidence that the diagnosis of CHD is being delayed and to focus on interventions to improve early diagnosis and referral.

Preoperative assessment of nutritional status:

A full preoperative assessment should be obtained as it provides essential baseline information for further monitoring of progress following surgical correction. This would typically include accurate measurements of height, weight, and head circumference. The measurement of biceps or triceps skinfold thickness is a simple method for determining fat stores, which is not routinely performed during preoperative assessment, 19 but might provide useful data for follow-up, both for individual patients and for patient groups. Laboratory tests that include plasma levels of albumin, transferrin, prealbumin, and retinol-binding protein are seldom undertaken because they are thought to be of limited value.

Nutritional support

Significant caloric supplementation in children with CHD could lead to improved growthReference Jackson and Poskitt 47 and, in some, improved growth could be achieved using continuous enteral feeds.Reference Bougle, Iselin, Kahyat and Duhamel 48 Reference Schwarz, Gewitz and See 50

Enteral nutrition is the preferred mode of nutritional support in paediatric ICUs.Reference Skillman and Mehta 51 Enteral nutrition is physiological, has a favourable effect on the intestinal mucosa, and has fewer complications compared with parenteral nutrition.Reference Zamberlan, Delgado, Leone, Feferbaum and Okay 52 , Reference Mehta 53 It has the additional benefit that it is considerably cheaper than parenteral nutrition and more easily available in low- and middle-income countries. Intragastric feeding is the most common route, and there are insufficient data to recommend routine use of post-pyloric feeding, unless there are particular concerns such as poor tolerance of gastric feeding or evidence of gastro-oesophageal reflux with aspiration. In a single randomised controlled trial in 74 critically ill children, a higher number of patients with post-pyloric feeding reached caloric goals.Reference Meert, Daphtary and Metheny 54

There are particular challenges with feeding of neonates before surgery, although in most cases it is possible to start enteral feeding – even while on prostaglandins. Many of these infants may continue to require gavage feeding postoperatively.Reference Natarajan, Reddy Anne and Aggarwal 55

Postoperative nutrition

Postoperative enteral feeds should be initiated as soon as possible, and parenteral nutrition should only be used if absolutely essential. Recent data suggest that early parenteral nutrition, within 7 days of admission, in the paediatric ICU is associated with worse patient outcomes, at least in high-income countries.Reference Fivez, Kerklaan and Mesotten 56

Initiation and advancement of feeds:

Guidelines for withholding feeds after paediatric cardiac surgery are not clearly defined, and there are extremely limited data available specific to low- and middle-income countries. The most common concern in early initiation of feeds is the potential for low cardiac output with gut hypoperfusion, especially in neonates with duct-dependent circulation, leading to necrotising enterocolitis.Reference Jeffries, Wells, Starnes, Wetzel and Moromisato 57 , Reference Giannone, Luce, Nankervis, Hoffman and Wold 58 With careful monitoring and slow advancement of feeds, early enteral nutrition is feasible in most neonates within the first 24 hours. In a retrospective review of 67 neonates, including 52 patients with duct-dependent circulation undergoing surgical repair, postoperative enteral feeds could be initiated within 3 days in 98.5% (n=66); 64 patients could reach full feeds at a median duration of 7.5 days following surgical correction.Reference Natarajan, Reddy Anne and Aggarwal 55

In neonates and young infants, feeds are typically started – within 12–24 hours of surgery – at 1 ml/kg/hour and advanced at the same rate every 4–6 hours to reach the goal volume. Although continuous feeds have not been shown to minimise aspiration or feed intolerance, it is sometimes resorted to in infants with poor weight gain and feeding complications.Reference Vanderhoof, Hofschire and Baluff 49 Feeds are withheld before extubation, around invasive procedures, in patients with haemodynamic instability, or with impending respiratory failure.

In the early postoperative phase, feed volume is dictated by the maintenance fluid rate. Fluid intake is usually restricted to 50–80% of maintenance rate in neonates and infants undergoing open-heart surgery.Reference Owens and Musa 59 On the basis of studies in patients with CHD, the resting energy expenditure is estimated to be 55–75 kcal/kg/day in the first 3–5 days.Reference De Wit, Meyer, Desai, Macrae and Pathan 60 This guides initial feeding, which can be escalated to 120–150 kcal/kg/day with transitioning to step down care to facilitate catch-up growth in infants.

Protein intake is crucial as protein catabolism could manifest as loss of respiratory muscle mass, failed weaning, poor weight gain, depressed immune function, and poor wound healing. In a small study from Brazil, patients became anabolic post-cardiac surgery with a calorie intake of 54 kcal/kg/day and a protein intake of 1.1 g/kg/day.Reference Teixeira-Cintra, Monteiro, Tremeschin, Trevilato, Halperin and Carlotti 42 The decline in C-reactive protein levels to values <2 is considered an indirect marker of the onset of the anabolic phase in critically ill patients; however, its relevance in post-cardiac surgical patients has not been proven.Reference Owens and Musa 59

For neonates and infants, particularly in low- and middle-income countries, human breast milk is the preferred form of enteral feeding, although the practicalities of maintaining breast milk production in this context may be challenging.Reference Torowicz, Seelhorst, Froh and Spatz 61 Breast milk is cost-effective, has immunological benefits, promotes better absorption of trace elements, and may even lower the risk of developing necrotising enterocolitis when used exclusively.Reference Sullivan, Schanler and Kim 62 In the setting where tight fluid restriction is required, it may be necessary to increase the energy density of feeds – both for formula and expressed breast milk. An energy density of ~1 kcal/ml is well tolerated. Further increases should be monitored carefully as high calorie density may precipitate osmotic diarrhoea. Cost-effective options to fortify formula feeds include additives such as coconut oil or medium-chain triglyceride oil.

A feeding gastrostomy or jejunostomy may be a reasonable option when long-term enteral nutrition is required in children.Reference Hofner, Behrens, Koch, Singer and Hofbeck 63 , Reference El-Sayed Ahmed, Alfares and Hynes 64 It may also be considered in patients with gastro-oesophageal reflux, aspiration, or severe failure to thrive. In a retrospective cohort of 54 patients who required gastrostomy tube placement after surgery for single-ventricle palliation, patients who underwent earlier placement of a gastrostomy tube had shorter ICU and hospital stays.Reference El-Sayed Ahmed, Alfares and Hynes 64

Monitoring enteral nutrition should include regular audits of weight, fluid and dietary intake, calories prescribed and calories achieved, gastrointestinal function, feeding tube integrity, and feeding complications. Undue attention to gastric residual volumes may be a deterrent to enteral feeding in critical care settings. Decisions to interrupt feeds should be considered with signs of feeding intolerance such as distention, vomiting, or diarrhoea, rather than relying on residual volumes alone.Reference Lee, Rogers and Chor 65 The most important aspect of monitoring enteral nutrition may be to detect and minimise interruptions in feeding. In a recent prospective study in a paediatric ICU, implementation of a stepwise enteral nutrition algorithm led to a significant decrease in the number of avoidable episodes of feeding interruptions (n=3 versus n=51, p=0.0001), shortened the time to reach energy goals from 4 days to 1 (p<0.0001), and resulted in a higher proportion of patients reaching their energy goals (99 versus 61%, p=0.01).Reference Hamilton, McAleer and Ariagno 66

Underfeeding is common in critically ill children even in most advanced units.Reference Martinez, Smallwood, Bechard, Graham and Mehta 67 Reference Mehta, Bechard, Zurakowski, Duggan and Heyland 69 Algorithm-led nutritional therapy and attention to energy and protein goals by dedicated nutrition support teams has translated to better postoperative outcomes in high-income countries.Reference Mehta, Bechard and Cahill 68 ,69 However, in emerging economies there is a perceived lack of dedicated nutrition support teams. A viable option is to use existing personnel in monitoring and supervising nutrition delivery. The initial phase should focus on education of in-house staff to bridge knowledge gaps in feeding practices.Reference Martinez, Bechard and Mehta 70 As primary caregivers, intensive care nurses should be empowered to initiate, monitor, and maintain nutrition delivery in the postoperative phase. A nutrition algorithm can be formulated to serve as a clinical aid to guide the therapy (Fig 2). This can be successfully integrated into multidisciplinary ICU rounds as nurse-led nutrition rounds.Reference Balachandran, Nair, Gopalraj, Vaidyanathan and Kumar 71

Figure 2 Nutritional management in the early postoperative period: suggested algorithm for low-resource environments. EBM=expressed breast milk.

There are very limited data on recommendations for feeding children who were previously underweight and failing to thrive. We recommend that such children be started on the nutritional programme as outlined above, together with close monitoring of progress and weight gain. Failure to gain weight should stimulate renewed focus on adequacy of the cardiac repair; the presence of complications such as chylothorax, with associated nutritional deficits; and the possibility of other underlying conditions that may cause malabsorption of enteral feeds. In addition, there needs to be focus on optimisation of the diet available to the child, and provision of supplements of essential macronutrients and micronutrients.

Parenteral nutrition

The overall use of parenteral nutrition in critical care settings in low- and middle-income countries is reported to be very low,Reference Ramakrishnan, Shankar, Ranganathan, Daphnee, Bharadwaj and Venkataraman 72 primarily owing to prohibitive costs and lack of dedicated personnel to ensure safe prescription and delivery. In addition, there are the biological complications related to parenteral nutrition including infection, venous thrombosis, electrolyte imbalances, and parenteral nutrition-induced cholestasis.Reference Heine and Bines 73 Notwithstanding these concerns, the use of parenteral nutrition may be warranted in critically ill patients after congenital heart surgery in situations in which enteral feeding is contraindicated or is insufficient to promote adequate growth. Guidelines are available for prescription of parenteral nutrition in children.Reference Koletzko, Goulet, Hunt, Krohn and Shamir 74 Prescription of parenteral nutrition is a complex process with potential for errors, requiring appropriate precautions and systems when used.Reference Boullata, Gilbert and Sacks 75

Parenteral nutrition in the low-resource environment:

In paediatric ICUs of low- and middle-income countries, parenteral nutrition should be prescribed only if absolutely indicated. The paediatric intensivist in conjunction with the nurse leader and the hospital clinical pharmacist should be in charge of prescribing and ensuring its safe administration. The feasibility of re-introducing enteral nutrition should be constantly explored. Trophic feeds should be encouraged wherever feasible to prevent intestinal mucosal atrophy.Reference Heine and Bines 73

Nutritional recovery after corrective surgery

Studies from advanced nations have previously reported normalisation of somatic growth typically 6–12 months after corrective congenital heart surgery.Reference Weintraub and Menahem 34 , Reference Cheung, Davis, Wilkinson and Weintraub 76 Weintraub et alReference Weintraub and Menahem 34 reported that after surgical closure of ventricular septal defects in infancy, growth parameters were almost comparable to the reference population by 5.7 years; however, in a study from southern India, the nutritional recovery on follow-up after ventricular septal defect closure in infancy was sub-optimal, with weight and height z-scores <−2 in 42 and 27% of patients, respectively.Reference Vaidyanathan, Roth, Gauvreau, Shivaprakasha, Rao and Kumar 77 In a larger study including all forms of CHD, the same authors reported significant catch-up growth after correction, typically within 3–12 months postoperatively, followed by plateauing of growth curves after 1 year.Reference Vaidyanathan, Radhakrishnan, Sarala, Sundaram and Kumar 78 This reflects an immediate catch-up growth in the short term owing to correction of the haemodynamic derangement. Other determinants of growth such as dietary and constitutional factors play a more important long-term role. Sub-optimal nutritional recovery with persistent weight, z-score <−2 was observed in 27% of patients and this was predicted by lower weight z-score at surgery, lower birth weight, and lower parental anthropometry.Reference Vaidyanathan, Radhakrishnan, Sarala, Sundaram and Kumar 78 It is important to identify patients at risk of sub-optimal recovery – those with lower growth potential – before intervention so that targeted nutritional rehabilitation may be provided on follow-up.

Review post-surgery and surgical recovery

Following paediatric ICU discharge, close attention to nutrition is required, particularly in some subsets of patientsReference Medoff-Cooper and Ravishankar 79 such as those with Fontan circulations following complex CHD.Reference Glockler, Severin and Arnold 80 However, this may pose challenges in resource-limited settings.

Future directions

Ideally, nutritional support for children with CHD should be based on data that are appropriate to specific environments. Although there is a reasonable body of published evidence on the existence of failure of growth and weight gain in children with CHD in low- and middle-income countries (see Supplementary Table 1), there are very limited data available on the optimum way to address these deficits.

Much of the current data on children with CHD are limited to a relatively small spectrum of cardiac anomalies. As increasingly complex CHD is addressed in low- and middle-income countries, the issues related to nutrition may well change and require different approaches. The maintenance of regional databases of information and outcomes would provide an ideal basis for future research in this area.

Much work needs to be done in the areas of quality control and research implementation in order to carry through what is already known into clinical practice. There may need to be increased focus on supporting teams and structures that are implemented for clinicians who work with patients with CHD in low- and middle-income countries.

Conclusions

The overall management of children with CHD may be complex, and attention to nutrition is a critical element of that care. In general, nutritional support is relatively inexpensive. However, it relies on the existence of a structured system within the cardiac care environment to ensure appropriate recognition of the particular role of nutrition in a specific child. Repeated and accurate measurement of growth parameters together with detailed attention to nutritional intake and tolerance are crucial. It makes little sense to invest in the expense of cardiac surgery while ignoring the associated nutritional challenges.

Acknowledgement

None.

Financial Support

This research received no specific grant from any funding agency, commercial, or not-for-profit sectors.

Conflicts of Interest

None.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S104795111700258X

References

1. Unger, R, DeKleermaeker, M, Gidding, SS, Christoffel, KK. Calories count. Improved weight gain with dietary intervention in congenital heart disease. Am J Dis Child 1992; 146: 10781084.CrossRefGoogle ScholarPubMed
2. Arodiwe, I, Chinawa, J, Ujunwa, F, Adiele, D, Ukoha, M, Obidike, E. Nutritional status of congenital heart disease (CHD) patients: burden and determinant of malnutrition at university of Nigeria teaching hospital Ituku – Ozalla, Enugu. Pak J Med Sci 2015; 31: 11401145.CrossRefGoogle ScholarPubMed
3. Cameron, JW, Rosenthal, A, Olson, AD. Malnutrition in hospitalized children with congenital heart disease. Arch Pediatr Adolesc Med 1995; 149: 10981102.CrossRefGoogle ScholarPubMed
4. Okoromah, CA, Ekure, EN, Lesi, FE, Okunowo, WO, Tijani, BO, Okeiyi, JC. Prevalence, profile and predictors of malnutrition in children with congenital heart defects: a case-control observational study. Arch Dis Child 2011; 96: 354360.CrossRefGoogle ScholarPubMed
5. Toole, BJ, Toole, LE, Kyle, UG, Cabrera, AG, Orellana, RA, Coss-Bu, JA. Perioperative nutritional support and malnutrition in infants and children with congenital heart disease. Congenit Heart Dis 2014; 9: 1525.CrossRefGoogle ScholarPubMed
6. Vaidyanathan, B, Nair, SB, Sundaram, KR, et al. Malnutrition in children with congenital heart disease (CHD) determinants and short term impact of corrective intervention. Indian Pediatr 2008; 45: 541546.Google ScholarPubMed
7. Varan, B, Tokel, K, Yilmaz, G. Malnutrition and growth failure in cyanotic and acyanotic congenital heart disease with and without pulmonary hypertension. Arch Dis Child 1999; 81: 4952.CrossRefGoogle ScholarPubMed
8. Venugopalan, P, Akinbami, FO, Al-Hinai, KM, Agarwal, AK. Malnutrition in children with congenital heart defects. Saudi Med J 2001; 22: 964967.Google ScholarPubMed
9. Villasis-Keever, MA, Aquiles Pineda-Cruz, R, Halley-Castillo, E, Alva-Espinosa, C. Frequency and risk factors associated with malnutrition in children with congenital cardiopathy. Salud Publica Mex 2001; 43: 313323.Google ScholarPubMed
10. Leite, HP, Fisberg, M, Novo, NF, Nogueira, EB, Ueda, IK. Nutritional assessment and surgical risk markers in children submitted to cardiac surgery. Sao Paulo Med J 1995; 113: 706714.CrossRefGoogle ScholarPubMed
11. Ehlers, KH. Growth failure in association with congenital heart disease. Pediatr Ann 1978; 7: 750759.CrossRefGoogle ScholarPubMed
12. Anderson, JB, Beekman, RH 3rd, Border, WL, et al. Lower weight-for-age z score adversely affects hospital length of stay after the bidirectional Glenn procedure in 100 infants with a single ventricle. J Thorac Cardiovasc Surg 2009; 138: 397404.e391.CrossRefGoogle ScholarPubMed
13. Schwalbe-Terilli, CR, Hartman, DH, Nagle, ML, et al. Enteral feeding and caloric intake in neonates after cardiac surgery. Am J Crit Care 2009; 18: 5257.CrossRefGoogle ScholarPubMed
14. Tchervenkov, CI, Jacobs, JP, Bernier, PL, et al. The improvement of care for paediatric and congenital cardiac disease across the world: a challenge for the World Society for Pediatric and Congenital Heart Surgery. Cardiol Young 2008; 18 (Suppl 2): 6369.CrossRefGoogle ScholarPubMed
15. Jenkins, KJ, Castaneda, AR, Cherian, KM, et al. Reducing mortality and infections after congenital heart surgery in the developing world. Pediatrics 2014; 134: e1422e1430.CrossRefGoogle ScholarPubMed
16. Vaidyanathan, B, Roth, SJ, Rao, SG, Gauvreau, K, Shivaprakasha, K, Kumar, RK. Outcome of ventricular septal defect repair in a developing country. J Pediatr 2002; 140: 736741.CrossRefGoogle ScholarPubMed
17. Reddy, NS, Kappanayil, M, Balachandran, R, et al. Preoperative determinants of outcomes of infant heart surgery in a limited-resource setting. Semin Thorac Cardiovasc Surg 2015; 27: 331338.CrossRefGoogle Scholar
18. Bernier, PL, Stefanescu, A, Samoukovic, G, Tchervenkov, CI. The challenge of congenital heart disease worldwide: epidemiologic and demographic facts. Semin Thorac Cardiovasc Surg Pediatr Card Surg Annu 2010; 13: 2634.CrossRefGoogle ScholarPubMed
19. Global Database on Child Growth and Malnutrition [Online]. 2017. Retrieved April 17, 2017 from http://www.who.int/nutgrowthdb/about/introduction/en/index5.html.Google Scholar
20. Van den Broeck, J, Meulemans, W, Eeckels, R. Nutritional assessment: the problem of clinical-anthropometrical mismatch. Eur J Clin Nutr 1994; 48: 6065.Google ScholarPubMed
21. Green Corkins, K. Nutrition-focused physical examination in pediatric patients. Nutr Clin Pract 2015; 30: 203209.CrossRefGoogle ScholarPubMed
22. Mehta, NM, Corkins, MR, Lyman, B, et al. Defining pediatric malnutrition: a paradigm shift toward etiology-related definitions. JPEN J Parenter Enteral Nutr 2013; 37: 460481.CrossRefGoogle ScholarPubMed
23. Becker, P, Carney, LN, Corkins, MR, et al. Consensus statement of the Academy of Nutrition and Dietetics/American Society for Parenteral and Enteral Nutrition: indicators recommended for the identification and documentation of pediatric malnutrition (undernutrition). Nutr Clin Pract 2015; 30: 147161.CrossRefGoogle Scholar
24. Blasquez, A, Clouzeau, H, Fayon, M, et al. Evaluation of nutritional status and support in children with congenital heart disease. Eur J Clin Nutr 2016; 70: 528531.CrossRefGoogle ScholarPubMed
25. Yahav, J, Avigad, S, Frand, M, et al. Assessment of intestinal and cardiorespiratory function in children with congenital heart disease on high-caloric formulas. J Pediatr Gastroenterol Nutr 1985; 4: 778785.Google ScholarPubMed
26. Thommessen, M, Heiberg, A, Kase, BF. Feeding problems in children with congenital heart disease: the impact on energy intake and growth outcome. Eur J Clin Nutr 1992; 46: 457464.Google ScholarPubMed
27. Hansen, SR, Dorup, I. Energy and nutrient intakes in congenital heart disease. Acta Paediatr 1993; 82: 166172.CrossRefGoogle ScholarPubMed
28. Nicholson, GT, Clabby, ML, Kanter, KR, Mahle, WT. Caloric intake during the perioperative period and growth failure in infants with congenital heart disease. Pediatr Cardiol 2013; 34: 316321.CrossRefGoogle ScholarPubMed
29. Menon, G, Poskitt, EM. Why does congenital heart disease cause failure to thrive? Arch Dis Child 1985; 60: 11341139.CrossRefGoogle ScholarPubMed
30. Barton, JS, Hindmarsh, PC, Scrimgeour, CM, Rennie, MJ, Preece, MA. Energy expenditure in congenital heart disease. Arch Dis Child 1994; 70: 59.CrossRefGoogle ScholarPubMed
31. Mitchell, IM, Davies, PS, Day, JM, Pollock, JC, Jamieson, MP. Energy expenditure in children with congenital heart disease, before and after cardiac surgery. J Thorac Cardiovasc Surg 1994; 107: 374380.CrossRefGoogle ScholarPubMed
32. Goulart, MR, Schuh, DS, Moraes, DW, Barbiero, SM, Pellanda, LC. Serum C-reactive protein levels and body mass index in children and adolescents with CHD. Cardiol Young 2017; 27: 10831089.CrossRefGoogle ScholarPubMed
33. Mehrizi, A, Drash, A. Growth disturbance in congenital heart disease. J Pediatr 1962; 61: 418429.CrossRefGoogle ScholarPubMed
34. Weintraub, RG, Menahem, S. Growth and congenital heart disease. J Paediatr Child Health 1993; 29: 9598.CrossRefGoogle ScholarPubMed
35. Ackerman, IL, Karn, CA, Denne, SC, Ensing, GJ, Leitch, CA. Total but not resting energy expenditure is increased in infants with ventricular septal defects. Pediatrics 1998; 102: 11721177.CrossRefGoogle Scholar
36. Salzer, HR, Haschke, F, Wimmer, M, Heil, M, Schilling, R. Growth and nutritional intake of infants with congenital heart disease. Pediatr Cardiol 1989; 10: 1723.CrossRefGoogle ScholarPubMed
37. Matthiesen, NB, Henriksen, TB, Gaynor, JW, et al. Congenital heart defects and indices of fetal cerebral growth in a nationwide cohort of 924 422 liveborn infants. Circulation 2016; 133: 566575.CrossRefGoogle Scholar
38. Villares, JM, Leal, LO, Diaz, IS, Gonzalez, PG. Plasma aminogram in infants operated on complex congenital heart disease. Nutr Hosp 2008; 23: 283287.Google ScholarPubMed
39. Leite, HP, de Camargo Carvalho, AC, Fisberg, M. Nutritional status of children with congenital heart disease and left-to-right shunt. The importance of the presence of pulmonary hypertension. Arq Bras Cardiol 1995; 65: 403407.Google ScholarPubMed
40. Steier, M, Lopez, R, Cooperman, JM. Riboflavin deficiency in infants and children with heart disease. Am Heart J 1976; 92: 139143.CrossRefGoogle ScholarPubMed
41. Finnerty, CC, Mabvuure, NT, Ali, A, Kozar, RA, Herndon, DN. The surgically induced stress response. JPEN J Parenter Enteral Nutr 2013; 37: 21s29s.CrossRefGoogle ScholarPubMed
42. Teixeira-Cintra, MA, Monteiro, JP, Tremeschin, M, Trevilato, TM, Halperin, ML, Carlotti, AP. Monitoring of protein catabolism in neonates and young infants post-cardiac surgery. Acta Paediatr 2011; 100: 977982.CrossRefGoogle Scholar
43. Mehta, NM, Costello, JM, Bechard, LJ, et al. Resting energy expenditure after Fontan surgery in children with single-ventricle heart defects. JPEN J Parenter Enteral Nutr 2012; 36: 685692.CrossRefGoogle ScholarPubMed
44. Jones, MO, Pierro, A, Hammond, P, Lloyd, DA. The effect of major operations on heart rate, respiratory rate, physical activity, temperature and respiratory gas exchange in infants. Eur J Pediatr Surg 1995; 5: 912.CrossRefGoogle ScholarPubMed
45. Hardin, JT, Muskett, AD, Canter, CE, Martin, TC, Spray, TL. Primary surgical closure of large ventricular septal defects in small infants. Ann Thorac Surg 1992; 53: 397401.CrossRefGoogle ScholarPubMed
46. Brooks, A, Geldenhuys, A, Zuhlke, L, Human, P, Zilla, P. Pulmonary artery banding: still a valuable option in developing countries? Eur J Cardiothorac Surg 2012; 41: 272276.CrossRefGoogle Scholar
47. Jackson, M, Poskitt, EM. The effects of high-energy feeding on energy balance and growth in infants with congenital heart disease and failure to thrive. Br J Nutr 1991; 65: 131143.CrossRefGoogle ScholarPubMed
48. Bougle, D, Iselin, M, Kahyat, A, Duhamel, JF. Nutritional treatment of congenital heart disease. Arch Dis Child 1986; 61: 799801.CrossRefGoogle ScholarPubMed
49. Vanderhoof, JA, Hofschire, PJ, Baluff, MA, et al. Continuous enteral feedings. An important adjunct to the management of complex congenital heart disease. Am J Dis Child 1982; 136: 825827.CrossRefGoogle Scholar
50. Schwarz, SM, Gewitz, MH, See, CC, et al. Enteral nutrition in infants with congenital heart disease and growth failure. Pediatrics 1990; 86: 368373.CrossRefGoogle ScholarPubMed
51. Skillman, HE, Mehta, NM. Nutrition therapy in the critically ill child. Curr Opinion Crit Care 2012; 18: 192198.CrossRefGoogle ScholarPubMed
52. Zamberlan, P, Delgado, AF, Leone, C, Feferbaum, R, Okay, TS. Nutrition therapy in a pediatric intensive care unit: indications, monitoring, and complications. JPEN J Parenter Enteral Nutr 2011; 35: 523529.CrossRefGoogle Scholar
53. Mehta, NM. Approach to enteral feeding in the PICU. Nutr Clin Pract 2009; 24: 377387.CrossRefGoogle ScholarPubMed
54. Meert, KL, Daphtary, KM, Metheny, NA. Gastric vs small-bowel feeding in critically ill children receiving mechanical ventilation: a randomized controlled trial. Chest 2004; 126: 872878.CrossRefGoogle ScholarPubMed
55. Natarajan, G, Reddy Anne, S, Aggarwal, S. Enteral feeding of neonates with congenital heart disease. Neonatology 2010; 98: 330336.CrossRefGoogle ScholarPubMed
56. Fivez, T, Kerklaan, D, Mesotten, D, et al. Early versus late parenteral nutrition in critically ill children. N Engl J Med 2016; 374: 11111122.CrossRefGoogle ScholarPubMed
57. Jeffries, HE, Wells, WJ, Starnes, VA, Wetzel, RC, Moromisato, DY. Gastrointestinal morbidity after Norwood palliation for hypoplastic left heart syndrome. Ann Thorac Surg 2006; 81: 982987.CrossRefGoogle ScholarPubMed
58. Giannone, PJ, Luce, WA, Nankervis, CA, Hoffman, TM, Wold, LE. Necrotizing enterocolitis in neonates with congenital heart disease. Life Sci 2008; 82: 341347.CrossRefGoogle ScholarPubMed
59. Owens, JL, Musa, N. Nutrition support after neonatal cardiac surgery. Nutr Clin Pract 2009; 24: 242249.CrossRefGoogle ScholarPubMed
60. De Wit, B, Meyer, R, Desai, A, Macrae, D, Pathan, N. Challenge of predicting resting energy expenditure in children undergoing surgery for congenital heart disease. Pediatr Crit Care Med 2010; 11: 496501.Google ScholarPubMed
61. Torowicz, DL, Seelhorst, A, Froh, EB, Spatz, DL. Human milk and breastfeeding outcomes in infants with congenital heart disease. Breastfeed Med 2015; 10: 3137.CrossRefGoogle ScholarPubMed
62. Sullivan, S, Schanler, RJ, Kim, JH, et al. An exclusively human milk-based diet is associated with a lower rate of necrotizing enterocolitis than a diet of human milk and bovine milk-based products. J Pediatr 2010; 156: 562567.e561.CrossRefGoogle ScholarPubMed
63. Hofner, G, Behrens, R, Koch, A, Singer, H, Hofbeck, M. Enteral nutritional support by percutaneous endoscopic gastrostomy in children with congenital heart disease. Pediatr Cardiol 2000; 21: 341346.CrossRefGoogle ScholarPubMed
64. El-Sayed Ahmed, MM, Alfares, FA, Hynes, CF, et al. Timing of gastrostomy tube feeding in three-stage palliation of single-ventricle physiology. Congenit Heart Dis 2016; 11: 3438.CrossRefGoogle ScholarPubMed
65. Lee, JH, Rogers, E, Chor, YK, et al. Optimal nutrition therapy in paediatric critical care in the Asia-Pacific and Middle East: a consensus. Asia Pacific J Clin Nutr 2016; 25: 676696.Google ScholarPubMed
66. Hamilton, S, McAleer, DM, Ariagno, K, et al. A stepwise enteral nutrition algorithm for critically ill children helps achieve nutrient delivery goals. Pediatr Crit Care Med 2014; 15: 583589.CrossRefGoogle ScholarPubMed
67. Martinez, EE, Smallwood, CD, Bechard, LJ, Graham, RJ, Mehta, NM. Metabolic assessment and individualized nutrition in children dependent on mechanical ventilation at home. J Pediatr 2015; 166: 350357.CrossRefGoogle ScholarPubMed
68. Mehta, NM, Bechard, LJ, Cahill, N, et al. Nutritional practices and their relationship to clinical outcomes in critically ill children – an international multicenter cohort study. Crit Care Med 2012; 40: 22042211.CrossRefGoogle ScholarPubMed
69. Mehta, NM, Bechard, LJ, Zurakowski, D, Duggan, CP, Heyland, DK. Adequate enteral protein intake is inversely associated with 60-d mortality in critically ill children: a multicenter, prospective, cohort study. Am J Clin Nutr 2015; 102: 199206.CrossRefGoogle ScholarPubMed
70. Martinez, EE, Bechard, LJ, Mehta, NM. Nutrition algorithms and bedside nutrient delivery practices in pediatric intensive care units: an international multicenter cohort study. Nutr Clin Pract 2014; 29: 360367.CrossRefGoogle ScholarPubMed
71. Balachandran, R, Nair, SG, Gopalraj, SS, Vaidyanathan, B, Kumar, RK. Dedicated pediatric cardiac intensive care unit in a developing country: Does it improve the outcome? Ann Pediatr Cardiol 2011; 4: 122126.CrossRefGoogle Scholar
72. Ramakrishnan, N, Shankar, B, Ranganathan, L, Daphnee, DK, Bharadwaj, A, Venkataraman, R. Parenteral nutrition support: beyond gut feeling? Quality control study of parenteral nutrition practices in a tertiary care hospital. Indian J Crit Care Med 2016; 20: 3639.Google ScholarPubMed
73. Heine, RG, Bines, JE. New approaches to parenteral nutrition in infants and children. J Paediatr Child Health 2002; 38: 433437.CrossRefGoogle ScholarPubMed
74. Koletzko, B, Goulet, O, Hunt, J, Krohn, K, Shamir, R. 1. Guidelines on Paediatric Parenteral Nutrition of the European Society of Paediatric Gastroenterology, Hepatology and Nutrition (ESPGHAN) and the European Society for Clinical Nutrition and Metabolism (ESPEN), supported by the European Society of Paediatric Research (ESPR). J Pediatr Gastroenterol Nutr 2005; 41 (Suppl 2): S1S87.CrossRefGoogle ScholarPubMed
75. Boullata, JI, Gilbert, K, Sacks, G, et al. A.S.P.E.N. clinical guidelines: parenteral nutrition ordering, order review, compounding, labeling, and dispensing. JPEN J Parenter Enteral Nutr 2014; 38: 334377.CrossRefGoogle ScholarPubMed
76. Cheung, MM, Davis, AM, Wilkinson, JL, Weintraub, RG. Long term somatic growth after repair of tetralogy of Fallot: evidence for restoration of genetic growth potential. Heart 2003; 89: 13401343.CrossRefGoogle ScholarPubMed
77. Vaidyanathan, B, Roth, SJ, Gauvreau, K, Shivaprakasha, K, Rao, SG, Kumar, RK. Somatic growth after ventricular septal defect in malnourished infants. J Pediatr 2006; 149: 205209.CrossRefGoogle ScholarPubMed
78. Vaidyanathan, B, Radhakrishnan, R, Sarala, DA, Sundaram, KR, Kumar, RK. What determines nutritional recovery in malnourished children after correction of congenital heart defects? Pediatrics 2009; 124: e294e299.CrossRefGoogle ScholarPubMed
79. Medoff-Cooper, B, Ravishankar, C. Nutrition and growth in congenital heart disease: a challenge in children. Curr Opin Cardiol 2013; 28: 122129.CrossRefGoogle ScholarPubMed
80. Glockler, M, Severin, T, Arnold, R, et al. First description of three patients with multifocal lymphangiomatosis and protein-losing enteropathy following palliation of complex congenital heart disease with total cavo-pulmonary connection. Pediatr Cardiol 2008; 29: 771774.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1 An approach to nutrition in the child with failure to grow or to gain weight, from Mehta et al.22

Figure 1

Figure 2 Nutritional management in the early postoperative period: suggested algorithm for low-resource environments. EBM=expressed breast milk.

Supplementary material: File

Argent et al supplementary material

Argent et al supplementary material

Download Argent et al supplementary material(File)
File 82.6 KB