Clinical and Experimental Pediatrics

Search

Search

Close


Warning: fopen(/home/virtual/pediatrics/journal/upload/ip_log/ip_log_2024-11.txt) [function.fopen]: failed to open stream: Permission denied in /home/virtual/pediatrics/journal/ip_info/view_data.php on line 93

Warning: fwrite(): supplied argument is not a valid stream resource in /home/virtual/pediatrics/journal/ip_info/view_data.php on line 94

All issues > Volume 58(3); 2015

Lee: Nutritional strategy of early amino acid administration in very low birth weight infants

Nutritional strategy of early amino acid administration in very low birth weight infants

Byong Sop Lee, MD, PhD1
Corresponding author: Byong Sop Lee, MD, PhD. Department of Pediatrics, Asan Medical Center, University of Ulsan College of Medicine, 88 Olympic-ro 43-gil, Songpa-gu, Seoul 138-736, Korea. Tel: +82-2-3010-3929, Fax: +82-2-3010-6978, mdleebs@amc.seoul.kr
Received October 14, 2014       Accepted February 16, 2015
Abstract
Relative to a fetus of the same gestational age, very low birth weight (VLBW) infants are more likely to be underfed and to undergo growth restriction during their early hospital stay. The current trend towards "early and aggressive" nutritional strategies in VLBW infants aims to overcome the early nutritional deficiency and thereby boost postnatal catch-up growth, simultaneously improving long-term neurodevelopmental outcomes. Although the minimum starting amino acid (AA) dose to prevent negative nitrogen balance is well established, the upper limit and the rate of increase of early AA doses are controversial. Most randomized controlled trials show that early and high-dose (target, 3.5 to 4.9 g/kg/day) AA regimens, with or without high nonprotein calories, do not improve long-term growth and neurodevelopment. High-dose AA supplementation may lead to early metabolic disturbances and excessive or disproportionate plasma AA levels, particularly in infants of very low gestational age. Further large studies are needed to clarify the optimal strategy for early administration of parenteral AA doses in VLBW infants.
Introduction
Introduction
Advances in parenteral nutrition (PN) have markedly improved survival rates of very low birth weight (VLBW) infants. However, a significant proportion of these infants still have growth restriction at hospital discharge1,2) and until adulthood3,4). Although both intrauterine growth restriction (IUGR) and postnatal growth restriction are well-known determinants of final growth outcome in preterm infants, postnatal growth restriction in particular, rather than IUGR status, is significantly associated with adverse neurodevelopmental outcomes during childhood5). Thus, whether "early and aggressive" nutritional support can normalize postnatal growth and simultaneously improve long-term neurodevelopmental outcome is one of the major interests in nutritional research of preterm infants.
Fetal nutrition has been regarded as the gold standard for postnatal nutritional therapy in preterm infants. According to the American Academy of Pediatrics' statement, the goal of postnatal nutrition in preterm infants is "to provide nutrition that will duplicate the in utero growth rate and body composition of the fetus at the same gestational age"6). However, this goal is difficult to achieve ex utero, particularly in the early days following birth. The recommended requirements for energy and protein intake, calculated by the factorial or empirical approaches, usually cannot be provided in VLBW infants because they are placed in highly humidified incubators and are frequently subjected to early fluid and nutritional restriction7,8). As enteral feeding is introduced, infants are gradually weaned from continual supplementation by PN, which mimics nutritional transfer from the placenta and would not be uninterrupted if they were in utero. Collectively, postnatal nutrition in VLBW infants cannot completely duplicate fetal nutrition quantitatively and qualitatively. This review will discuss early nutrition and the growth and developmental outcomes in VLBW infants, with a focus on amino acids (AA), the main building block of cell growth.
Early nutrition in VLBW infants: how does it differ from fetal nutrition?
Early nutrition in VLBW infants: how does it differ from fetal nutrition?
The fetus needs a variety of substrates from the placenta for successful growth. Regarding the macronutrients, normal fetal nutrition can be briefly characterized as follows: AAs are transferred from the placenta at rates greater than that needed for net protein accretion within the fetus. The excess AAs are oxidized and contribute up to 20% of the fetus's total energy expenditure9). Glucose transfer is determined by maternal serum glucose concentration and occurs at rates that meet fetal requirements10). Lipids contribute minimally to the energy expenditure until the late part of the third trimester. Fat deposition increases markedly from the early third trimester and contributes to 10% to 15% of the fetus's body weight at term11,12). Current textbook recommendations for early PN in preterm infants advise higher lipid and lower protein intake than those required by the fetus13,14). Administration of intravenous lipid emulsion is usually recommended beginning at birth or postnatal day 1, and is encouraged to rapidly advance to 3.0 to 4.0 g/kg/day as long as hypertriglyceridemia does not develop. The short-term safety of a 20% lipid emulsion in preterm infants in terms of respiratory morbidities and metabolic abnormalities (such as hyperglycemia) has been confirmed, even during the early postnatal days15). However, reports of the higher adiposity and abnormal fat distribution in preterm infants relative to newborn infants at term equivalent age have raised concerns about these lipid-focused early nutritional strategies16,17). As for AA, factorial analysis reveals a decreasing requirement of AA as the fetus grows18) and a recent recommendation was provided for AA dosing to reflect this shift in fetal protein requirement19,20). However, neonatologists often increase the AA dose as the infant approaches hospital discharge because a significant proportion of preterm infants are considered to be behind their "healthy" peers (i.e., fetuses of the same gestational age) in terms of growth (Fig. 1).
Optimal growth standard for very preterm infants
Optimal growth standard for very preterm infants
An intrauterine growth chart that represents overall fetal growth in a specific population is needed to assess the optimal postnatal nutritional care in preterm infants. Since the 1960s, numerous fetal growth curves have been developed from various subpopulations. Among these, Fenton's growth chart has been updated recently based on a meta-analysis of large population-based studies and is widely accepted for its high methodological quality21,22). A postnatal growth curve is another alternative to determine the growth standard for VLBW infants. However, if data are derived from preterm infants, "sick" survivors should be excluded to minimize the influence of postnatal conditions. Postnatal growth of individual preterm infants is determined by prenatal factors that caused preterm birth and by postnatal conditions, including various illnesses and nutritional practices23,24,25). However, data on the postnatal growth chart beyond the neonatal period are scarce. A growth reference chart derived from data of the Infant Health and Developmental Program (IHDP), which includes a large number of patients with longitudinally collected data from 40 weeks gestational age to 36 months, is recommended for VLBW infants requiring long-term follow-up26). However, the primary weakness of the IHDP growth chart is that the children analyzed were born in 1985 and likely had different medical and nutritional care than those of the current era.
The decision to adopt "fetal" or "postnatal" growth curve depends on the purpose for which it is used. The fetal growth curve is useful to compare VLBW infants with a normally growing fetus and may alert caregivers to increase calorie and/or protein supplementation to boost early catch-up growth. Meanwhile, the postnatal growth curve is useful to compare VLBW infants with their clinically stable peers as they receive "standard" nutritional care. Although this comparison may be reassuring to many caregivers, it may increase the proportion of preterm infants diagnosed with extrauterine growth restriction, at least by definition. Whether clinicians should promote early catch-up growth is a primary focus of nutritional studies of preterm infants with extrauterine growth restriction. Despite a potential benefit in neurodevelopmental outcomes5,27), the detrimental effect of rapid catch-up growth on cardiovascular and metabolic health in adulthood is an increasing concern, especially for infants born with relatively low birth weight or IUGR28,29). The rest of this article will summarize and discuss the results of recent randomized controlled trials that investigate the impact of early AA intervention on short- and long-term growth as well as neurodevelopmental outcomes in VLBW infants.
Optimal dose of early AA intake and metabolic influence
Optimal dose of early AA intake and metabolic influence
The most consistent finding in research on early nutrition of preterm infants is that increased protein intake produces greater gains in protein balance and that AA oxidation increases directly with supply30). To prevent negative nitrogen balance in VLBW infants, the recommended minimal starting dose of AA is 1.0 to 1.5 g/kg/day31). Below this, a loss of body protein is observed at a rate inversely related to gestational age. Protein loss in very preterm infants is approximately two folds greater than that in full-term newborn infants32). Prolonged deprivation of specific AAs, such as leucine, reduces insulin secretion and may lead to early hyperkalemia and hyperglycemia in newborn infants. However, early high-dose AA supplementation has not been shown to consistently prevent insulin-associated metabolic abnormalities better than standard doses33,34,35,36).
Although the lower limit of AA dose is generally confirmed among experts, whether the "fetal dose of AA" should be administered to VLBW infants in the early days of life is controversial. As noted earlier, the postnatal AA dose needed to maintain fetal protein accretion rate is at least 3.0 to 3.5 g/kg/day with an energy intake of more than 100 kcal/kg/day19,31,37). With respect to starting high AA dose from the early days of life, there has been concern about the risk of excessive products from AA metabolism. Fortunately, many comparative studies do not show a difference in the pH value or base deficit between groups taking different AA doses (the initial dose of AA ranged from 0 to 3.0 g/kg/day with a target range of 2.4 to 4.0 g/kg/day)33,34,38,39,40). Another concern regarding a high starting dose of AA is the risk of excessively high blood urea nitrogen (BUN) level. Several randomized controlled trials comparing high vs. standard doses of early AA doses show that patients taking high-dose AA have a significantly higher BUN than those taking standard-dose AA although the clinical implication of this difference is not clear. The suggested reference range for fetal BUN is 21.0 to 40.1 mg/dL34), but the safety limit in terms of brain development in very preterm infants is unknown. Whether elevated BUN level indicates AA intolerance and can be an indicator to withhold AA infusion remains controversial33,40,41,42). In practice, the AA infusion was frequently discontinued in infants with extremely low gestational age (≤24 weeks) particularly when accompanied by high ammonia levels33). Daily monitoring of individual AA level by comparing it with reference data can be a promising solution. Several types of automatic AA analyzers that use ion exchange chromatography or tandem mass spectrometry are available although their use is limited to research purposes41,42).
The influence of early AA intake on calcium and phosphorus homeostasis was reported recently in a study by Bonsante et al.43). Preterm infants (gestational age≤33 weeks) were divided into 3 groups according to their mean AA intake during the first week of life. The incidences of hypophosphatemia and hypercalcemia, respectively, were increased in the high (>2 g/kg/day of mean AA intake) AA intake group relative to the moderate (1.5-2 g/kg/day) and low (<1.5 g/kg/day) intake groups. This phenomenon is known as "Placental Incompletely Restored Feeding (PI-ReFeeding) syndrome". The proposed underlying mechanism behind this imbalance in serum calcium and phosphorus is that maintenance of anabolic status through parenteral AA and energy intake promotes cellular uptake of phosphorus, which leads to increased mobilization of calcium from the bones and hypercalcemia in the absence of adequate phosphorus intake. Although the clinical implication of this alteration remains unclear, it may increase the risk of bone mineralization defects in preterm infants44).
Early nutrition and neonatal morbidities
Early nutrition and neonatal morbidities
Does early nutritional strategy modify the course of critical illnesses in VLBW infants? Ehrenkranz et al.45) reported an association of the severity of illnesses with the early nutritional status. In a large study that analyzed the trial on parenteral glutamine supplementation performed by the Neonatal Research Network46), infants who were "less critically ill" received significantly greater amounts of parenteral and enteral nutrition during the first 3 weeks of life than infants who were classified as "more critically ill." Interestingly, those who were less critically ill also had a lower incidence of bronchopulmonary dysplasia (BPD), late-onset sepsis, and death, and a shorter duration of hospital stay, although the incidence of necrotizing enterocolitis was not different. However, the definition of "critically ill" in this study was somewhat arbitrary, as it was based on the duration of ventilator-dependency during the first 7 days of life. Additionally, the retrospective nature of this study also limits the ability to determine a causal relationship between early nutrition and neonatal morbidities. Most randomized trials fail to demonstrate a benefit of high-dose AA supplementation for reducing neonatal morbidities (see below for further discussion).
The role of nutrition for the prevention and management of BPD is of particular interest because malnutrition has a direct negative effect on the developing lung in humans and rats47,48). To date, no randomized controlled study has addressed the effect of early nutritional therapy on respiratory morbidities in preterm infants. In a limited number of prospective studies focused on growth and developmental outcomes, the incidence of BPD did not differ between those who received "early and/or higher AA intake" and those who received conventional timing and doses of AA49,50,51). Two studies have shown an association between the risk of BPD and delayed or lower quantity of enteral (but not parenteral) nutrition52,53). Because fluid intake is closely linked to calorie intake in the early neonatal period, it may confound the association between early nutrition and BPD. In a recent Cochrane Review, the fluid-restricted group tended to have a nonsignificant trend towards reduced incidence of BPD relative to the group with liberal fluid intake54). In another large retrospective study, high fluid intake during the first 10 days of life was associated with an increased risk of BPD in extremely low birth weight infants55). However, total fluid intakes reported in these early studies were considerably higher than those recommended by current protocols for VLBW infants typically managed in highly humidified incubators56).
Early parenteral amino acid doses and growth outcomes
Early parenteral amino acid doses and growth outcomes
One of the goals of early and aggressive PN is to minimize the initial growth deficit and maintain the fetal growth rate in each growth parameter. However, a benefit of early and high AA regimen (with or without an increase in overall calorie intake) on neonatal growth is not clear in most comparative randomized controlled trials51,57,58,59,60) (Table 1). Most studies show that growth parameters measured at 28 days of life and 36 weeks of corrected gestational age are not different between the early high-dose AA and conventional regimens. Only a recent study using a SCAMP (Standardized, Concentrated with Added Macronutrients Parenteral) nutrition regimen comprised of high doses of AA, glucose, and lipid, demonstrated greater head growth50) with a mean difference corresponding to 6% and 5% difference in brain weight at 28 days of life and 36 weeks of corrected gestational age, respectively. However, further research is necessary to determine whether the difference in head circumference can be maintained beyond infancy and translated into better neurodevelopmental outcomes.
Early parenteral amino acid doses and neurodevelopmental outcomes
Early parenteral amino acid doses and neurodevelopmental outcomes
The timing of nutritional deprivation is an important determinant of brain development. For example, preferential gene expression toward cell proliferation and differentiation in rats occurs around postnatal day 7, which is roughly equivalent to 32 to 36 weeks gestation in the human brain61). The human brain undergoes remarkable structural and functional changes between 24 to 42 weeks' gestation62), which implies that even a brief period of nutritional deficiency experienced during the early days of life can impair neurodevelopmental outcomes in VLBW infants.
A few clinical trials have investigated the relationship between the early AA intervention and long-term neurodevelopmental outcomes49,57,59). Despite common study designs with a target AA dose of 4.0 g/kg/day in the intervention groups, most studies failed to show better neurodevelopmental outcomes at various follow-up points. The study by Tan et al.59) was the only one to show that cumulative energy and AA deficits at 28 days correlated significantly with Bayley Scale of Infantile Development scores at 3 months in the entire cohort. However, this was not significant at 9 months postterm and the study did not show differences in the total or cortical brain volumes at 40 weeks' postconception. Similarly, Burattini et al.57) showed that an additional 8 g/kg of AA during the first 10 days of life did not improve the neurodevelopmental scores at 2 years of age. A series of studies by Blanco et al.33,49,63) showed that early and high-dose AA supplementation in extremely low birth weight infants was related to worse neurodevelopmental outcomes at 18 months of corrected age, though these were temporary. Although this analysis was limited by the high rate of loss to follow-up (about 50%), the potential toxicity of specific plasma AA on the developing brain in the high-dose AA group should not be overlooked63). In the studies that investigated the plasma AA levels after infusion of AA mixtures40,42,63,64), the study was designed so that the most premature infants received the highest doses of AA. As expected, the mean AA concentrations of the study by Blanco were greater than those in other studies. In addition, the specific essential (isoleucine, leucine, valine, phenylalanine, lysine, and methionine) and nonessential (proline) AAs were significantly higher in the intervention group than in the control group. In particular, leucine remained significantly higher for up to 7 days. Abnormal concentrations of branched-chain AAs have been related to impaired brain growth and development, possibly due to impairments with tissue protein synthesis/degradation, catabolism of other branched-chain AAs, and transport of large neutral AAs to the brain65). Studies comparing different doses and mixtures of AA supplements are needed to elucidate whether these differences are due to the high AA dose or the relative proportions of AAs in the mixture66).
Conclusion
Conclusion
Due to the high risk of growth failure and neurodevelopmental impairment in many VLBW infants, many neonatologists and nutritional experts suggest "early and aggressive" nutritional strategies with a primary goal of mimicking the AA dose that the fetus would receive in utero. However, the number of trials that compare standard and high-dose AA supplementation is limited and the benefits of such dosing on growth and developmental outcomes are unclear. The recent finding of an association between early high-dose supplementation and abnormal plasma AA levels, a protocol commonly used in extremely premature infants, indicates the need for an individualized approach to nutritional intervention. As for early parenteral AA nutrition, whether to follow the paradigm of "the more, the better" or "too much is as bad as too little" is still debatable. Further large studies are needed to clarify the safest and most effective strategy for early parenteral AA in VLBW infants.
Conflicts of interest

No potential conflict of interest relevant to this article was reported.

References
1. Kim ES, Sohn JA, Lee EH, Choi EJ, Lee HJ, Lee JA, et al. Extrauterine growth restriction in very low birth weight infants. J Korean Soc Neonatol 2010;17:53–63.
2. Lemons JA, Bauer CR, Oh W, Korones SB, Papile LA, Stoll BJ, et al. Very low birth weight outcomes of the National Institute of Child health and human development neonatal research network, January 1995 through December 1996. NICHD Neonatal Research Network. Pediatrics 2001;107:E1
[Article] [PubMed]
3. Hack M, Schluchter M, Cartar L, Rahman M, Cuttler L, Borawski E. Growth of very low birth weight infants to age 20 years. Pediatrics 2003;112(1 Pt 1): e30–e38.
[Article] [PubMed]
4. Saigal S, Stoskopf B, Streiner D, Paneth N, Pinelli J, Boyle M. Growth trajectories of extremely low birth weight infants from birth to young adulthood: a longitudinal, population-based study. Pediatr Res 2006;60:751–758.
[Article] [PubMed]
5. Casey PH, Whiteside-Mansell L, Barrett K, Bradley RH, Gargus R. Impact of prenatal and/or postnatal growth problems in low birth weight preterm infants on school-age outcomes: an 8-year longitudinal evaluation. Pediatrics 2006;118:1078–1086.
[Article] [PubMed]
6. American Academy of Pediatrics Committee on Nutrition: Nutritional needs of low-birth-weight infants. Pediatrics 1985;75:976–986.
[Article] [PubMed]
7. Kashyap S, Schulze KF, Ramakrishnan R, Dell RB, Heird WC. Evaluation of a mathematical model for predicting the relationship between protein and energy intakes of low-birth-weight infants and the rate and composition of weight gain. Pediatr Res 1994;35:704–712.
[Article] [PubMed]
8. Ziegler EE, Thureen PJ, Carlson SJ. Aggressive nutrition of the very low birthweight infant. Clin Perinatol 2002;29:225–244.
[Article] [PubMed]
9. Gudinchet F, Schutz Y, Micheli JL, Stettler E, Jéquier E. Metabolic cost of growth in very low-birth-weight infants. Pediatr Res 1982;16:1025–1030.
[Article] [PubMed]
10. Baumann MU, Deborde S, Illsley NP. Placental glucose transfer and fetal growth. Endocrine 2002;19:13–22.
[Article] [PubMed]
11. McClellan R, Novak D. Fetal nutrition: how we become what we are. J Pediatr Gastroenterol Nutr 2001;33:233–244.
[Article] [PubMed]
12. Sparks JW, Girard JR, Battaglia FC. An estimate of the caloric requirements of the human fetus. Biol Neonate 1980;38:113–119.
[Article] [PubMed]
13. Poindexter BB, Denne SC. Parenteral nutrition. In: Gleason CA, Devaskar S, editors. Avery's disease of the newborn. 9th ed. Philadelphia: Saunders, 2012:963–971.
14. Poindexter BB, Denne SC. Nutrition and metabolism in the high-risk neonate. In: Martin RJ, Fanaroff AA, Walsh MC, editors. Fanaroff and Martin's neonatal perinatal medicine: diseases of the fetus and infant. 9th ed. St. Louis: Elsevier, 2011:643–668.
15. Murdock N, Crighton A, Nelson LM, Forsyth JS. Low birthweight infants and total parenteral nutrition immediately after birth. II. Randomised study of biochemical tolerance of intravenous glucose, amino acids, and lipid. Arch Dis Child Fetal Neonatal Ed 1995;73:F8–F12.
[Article] [PubMed] [PMC]
16. Uthaya S, Thomas EL, Hamilton G, Dore CJ, Bell J, Modi N. Altered adiposity after extremely preterm birth. Pediatr Res 2005;57:211–215.
[Article] [PubMed]
17. Griffin IJ, Cooke RJ. Development of whole body adiposity in preterm infants. Early Hum Dev 2012;88(Suppl 1): S19–S24.
[Article]
18. Ziegler EE. Protein requirements of very low birth weight infants. J Pediatr Gastroenterol Nutr 2007;45(Suppl 3): S170–S174.
[Article] [PubMed]
19. De Curtis M, Rigo J. The nutrition of preterm infants. Early Hum Dev 2012;88(Suppl 1): S5–S7.
[Article] [PubMed]
20. Agostoni C, Buonocore G, Carnielli VP, De Curtis M, Darmaun D, Decsi T, et al. Enteral nutrient supply for preterm infants: commentary from the European Society of Paediatric Gastroenterology, Hepatology and Nutrition Committee on Nutrition. J Pediatr Gastroenterol Nutr 2010;50:85–91.
[Article] [PubMed]
21. Fenton TR, Kim JH. A systematic review and meta-analysis to revise the Fenton growth chart for preterm infants. BMC Pediatr 2013;13:59
[Article] [PubMed] [PMC]
22. Fenton TR. A new growth chart for preterm babies: Babson and Benda's chart updated with recent data and a new format. BMC Pediatr 2003;3:13
[Article] [PubMed] [PMC]
23. Diekmann M, Genzel-Boroviczény O, Zoppelli L, von Poblotzki M. Postnatal growth curves for extremely low birth weight infants with early enteral nutrition. Eur J Pediatr 2005;164:714–723.
[Article] [PubMed]
24. Ehrenkranz RA, Younes N, Lemons JA, Fanaroff AA, Donovan EF, Wright LL, et al. Longitudinal growth of hospitalized very low birth weight infants. Pediatrics 1999;104(2 Pt 1): 280–289.
[Article] [PubMed]
25. Pauls J, Bauer K, Versmold H. Postnatal body weight curves for infants below 1000 g birth weight receiving early enteral and parenteral nutrition. Eur J Pediatr 1998;157:416–421.
[Article] [PubMed]
26. Sherry B, Mei Z, Grummer-Strawn L, Dietz WH. Evaluation of and recommendations for growth references for very low birth weight (< or =1500 grams) infants in the United States. Pediatrics 2003;111(4 Pt 1): 750–758.
[Article] [PubMed]
27. Latal-Hajnal B, von Siebenthal K, Kovari H, Bucher HU, Largo RH. Postnatal growth in VLBW infants: significant association with neurodevelopmental outcome. J Pediatr 2003;143:163–170.
[Article] [PubMed]
28. Barker DJ, Eriksson JG, Forsen T, Osmond C. Fetal origins of adult disease: strength of effects and biological basis. Int J Epidemiol 2002;31:1235–1239.
[Article] [PubMed]
29. Rogers LK, Velten M. Maternal inflammation, growth retardation, and preterm birth: insights into adult cardiovascular disease. Life Sci 2011;89:417–421.
[Article] [PubMed]
30. Denne SC, Poindexter BB. Evidence supporting early nutritional support with parenteral amino acid infusion. Semin Perinatol 2007;31:56–60.
[Article] [PubMed]
31. Embleton ND. Optimal protein and energy intakes in preterm infants. Early Hum Dev 2007;83:831–837.
[Article] [PubMed]
32. Denne SC, Karn CA, Ahlrichs JA, Dorotheo AR, Wang J, Liechty EA. Proteolysis and phenylalanine hydroxylation in response to parenteral nutrition in extremely premature and normal newborns. J Clin Invest 1996;97:746–754.
[Article] [PubMed] [PMC]
33. Blanco CL, Falck A, Green BK, Cornell JE, Gong AK. Metabolic responses to early and high protein supplementation in a randomized trial evaluating the prevention of hyperkalemia in extremely low birth weight infants. J Pediatr 2008;153:535–540.
[Article] [PubMed]
34. te Braake FW, van den Akker CH, Wattimena DJ, Huijmans JG, van Goudoever JB. Amino acid administration to premature infants directly after birth. J Pediatr 2005;147:457–461.
[Article] [PubMed]
35. Yang S, Lee BS, Park HW, Choi YS, Chung SH, Kim JH, et al. Effect of high vs standard early parenteral amino acid supplementation on the growth outcomes in very low birth weight infants. JPEN J Parenter Enteral Nutr 2013;37:327–334.
[Article] [PubMed]
36. Bonsante F, Iacobelli S, Chantegret C, Martin D, Gouyon JB. The effect of parenteral nitrogen and energy intake on electrolyte balance in the preterm infant. Eur J Clin Nutr 2011;65:1088–1093.
[Article] [PubMed]
37. van Goudoever JB, Sulkers EJ, Lafeber HN, Sauer PJ. Short-term growth and substrate use in very-low-birth-weight infants fed formulas with different energy contents. Am J Clin Nutr 2000;71:816–821.
[Article] [PubMed]
38. Jadhav P, Parimi PS, Kalhan SC. Parenteral amino acid and metabolic acidosis in premature infants. JPEN J Parenter Enteral Nutr 2007;31:278–283.
[Article] [PubMed] [PMC]
39. Porcelli PJ Jr, Sisk PM. Increased parenteral amino acid administration to extremely low-birth-weight infants during early postnatal life. J Pediatr Gastroenterol Nutr 2002;34:174–179.
[Article] [PubMed]
40. Bulbul A, Okan F, Bulbul L, Nuhoglu A. Effect of low versus high early parenteral nutrition on plasma amino acid profiles in very low birth-weight infants. J Matern Fetal Neonatal Med 2012;25:770–776.
[Article] [PubMed]
41. Ridout E, Melara D, Rottinghaus S, Thureen PJ. Blood urea nitrogen concentration as a marker of amino-acid intolerance in neonates with birth weight less than 1250 g. J Perinatol 2005;25:130–133.
[Article] [PubMed]
42. Thureen PJ, Melara D, Fennessey PV, Hay WW Jr. Effect of low versus high intravenous amino acid intake on very low birth weight infants in the early neonatal period. Pediatr Res 2003;53:24–32.
[Article] [PubMed]
43. Bonsante F, Iacobelli S, Latorre G, Rigo J, De Felice C, Robillard PY, et al. Initial amino acid intake influences phosphorus and calcium homeostasis in preterm infants: it is time to change the composition of the early parenteral nutrition. PLoS One 2013;8:e72880
[Article] [PubMed] [PMC]
44. Vachharajani AJ, Mathur AM, Rao R. Metabolic bone disease of prematurity. Neoreviews 2009;10:e402–e411.
[Article]
45. Ehrenkranz RA, Das A, Wrage LA, Poindexter BB, Higgins RD, Stoll BJ, et al. Early nutrition mediates the influence of severity of illness on extremely LBW infants. Pediatr Res 2011;69:522–529.
[Article] [PubMed] [PMC]
46. Poindexter BB, Ehrenkranz RA, Stoll BJ, Wright LL, Poole WK, Oh W, et al. Parenteral glutamine supplementation does not reduce the risk of mortality or late-onset sepsis in extremely low birth weight infants. Pediatrics 2004;113:1209–1215.
[Article] [PubMed]
47. Massaro D, Massaro GD. Hunger disease and pulmonary alveoli. Am J Respir Crit Care Med 2004;170:723–724.
[Article] [PubMed]
48. Massaro D, Massaro GD, Baras A, Hoffman EP, Clerch LB. Calorie-related rapid onset of alveolar loss, regeneration, and changes in mouse lung gene expression. Am J Physiol Lung Cell Mol Physiol 2004;286:L896–L906.
[Article] [PubMed]
49. Blanco CL, Gong AK, Schoolfield J, Green BK, Daniels W, Liechty EA, et al. Impact of early and high amino acid supplementation on ELBW infants at 2 years. J Pediatr Gastroenterol Nutr 2012;54:601–607.
[Article] [PubMed]
50. Morgan C, McGowan P, Herwitker S, Hart AE, Turner MA. Postnatal head growth in preterm infants: a randomized controlled parenteral nutrition study. Pediatrics 2014;133:e120–e128.
[Article] [PubMed]
51. Tan MJ, Cooke RW. Improving head growth in very preterm infants--a randomised controlled trial I: neonatal outcomes. Arch Dis Child Fetal Neonatal Ed 2008;93:F337–F341.
[Article] [PubMed]
52. Wemhöner A, Ortner D, Tschirch E, Strasak A, Rudiger M. Nutrition of preterm infants in relation to bronchopulmonary dysplasia. BMC Pulm Med 2011;11:7
[Article] [PubMed] [PMC]
53. Richard M, Ramful D, Robillard PY, Mussard C, Loumouamou Y, Ogier M, et al. Prevalence, severity, and predictors of bronchopulmonary dysplasia in a cohort of very preterm infants. Arch Pediatr 2013;20:928–937.
[Article] [PubMed]
54. Bell EF, Acarregui MJ. Restricted versus liberal water intake for preventing morbidity and mortality in preterm infants. Cochrane Database Syst Rev 2008;(1): CD000503
[PubMed]
55. Oh W, Poindexter BB, Perritt R, Lemons JA, Bauer CR, Ehrenkranz RA, et al. Association between fluid intake and weight loss during the first ten days of life and risk of bronchopulmonary dysplasia in extremely low birth weight infants. J Pediatr 2005;147:786–790.
[Article] [PubMed]
56. Kim SM, Lee EY, Chen J, Ringer SA. Improved care and growth outcomes by using hybrid humidified incubators in very preterm infants. Pediatrics 2010;125:e137–e145.
[Article] [PubMed]
57. Burattini I, Bellagamba MP, Spagnoli C, D'Ascenzo R, Mazzoni N, Peretti A, et al. Targeting 2.5 versus 4 g/kg/day of amino acids for extremely low birth weight infants: a randomized clinical trial. J Pediatr 2013;163:1278–1282.e1.
[Article] [PubMed]
58. Clark RH, Chace DH, Spitzer AR. Pediatrix Amino Acid Study Group. Effects of two different doses of amino acid supplementation on growth and blood amino acid levels in premature neonates admitted to the neonatal intensive care unit: a randomized, controlled trial. Pediatrics 2007;120:1286–1296.
[Article] [PubMed]
59. Tan M, Abernethy L, Cooke R. Improving head growth in preterm infants--a randomised controlled trial II: MRI and developmental outcomes in the first year. Arch Dis Child Fetal Neonatal Ed 2008;93:F342–F346.
[Article] [PubMed]
60. Vlaardingerbroek H, Vermeulen MJ, Rook D, van den Akker CH, Dorst K, Wattimena JL, et al. Safety and efficacy of early parenteral lipid and high-dose amino acid administration to very low birth weight infants. J Pediatr 2013;163:638–644. e1-e5.
[Article] [PubMed]
61. Stead JD, Neal C, Meng F, Wang Y, Evans S, Vazquez DM, et al. Transcriptional profiling of the developing rat brain reveals that the most dramatic regional differentiation in gene expression occurs postpartum. J Neurosci 2006;26:345–353.
[Article] [PubMed] [PMC]
62. Georgieff MK. Nutrition and the developing brain: nutrient priorities and measurement. Am J Clin Nutr 2007;85:614S–620S.
[Article] [PubMed]
63. Blanco CL, Gong AK, Green BK, Falck A, Schoolfield J, Liechty EA. Early changes in plasma amino acid concentrations during aggressive nutritional therapy in extremely low birth weight infants. J Pediatr 2011;158:543–548.e1.
[Article] [PubMed]
64. Poindexter BB, Ehrenkranz RA, Stoll BJ, Koch MA, Wright LL, Oh W, et al. Effect of parenteral glutamine supplementation on plasma amino acid concentrations in extremely low-birth-weight infants. Am J Clin Nutr 2003;77:737–743.
[Article] [PubMed]
65. Harper AE, Miller RH, Block KP. Branched-chain amino acid metabolism. Annu Rev Nutr 1984;4:409–454.
[Article] [PubMed]
66. Saenz de Pipaon M, Quero J, Wattimena DJ, Sauer PJ. Effect of two amino acid solutions on leucine turnover in preterm infants. Biol Neonate 2005;87:236–241.
[Article] [PubMed]
Fig. 1
A sample nutritional plot of a female baby with a birth weight of 860 g born at 26+0 weeks gestation. An amino acid (AA) dose of 3.0 g/kg/day was started on the first day of life. Initiation of enteral feeding was delayed for 10 days after birth due to meconium plug syndrome and was withheld for symptomatic patent ductus arteriosus requiring surgical ligation (at 21-22 days) and transient sign of feeding intolerance at 40 days. Full enteral feeding was achieved with fortified breast milk at 32 days, but the recommended dose of AA could not be reached until 8 weeks after birth. Each graded pentagon indicates the recommended range of AA intake in preterm infants who do not require catch-up growth at 26 to 30 weeks, 30 to 36 weeks, and 36 to 40 weeks after conception, respectively (Data from De Curtis et al. Early Hum Dev 2012;88:S5-7.19)).
kjped-58-77-g001
Table 1
Summary of recent randomized controlled trials on early parenteral amino acid intervention and growth and neurodevelopmental outcomes
kjped-58-77-i001

AA, amino acid; HAA, high amino acid; SAA, standard amino acid; GA, gestational age; HC, head circumference; PMA, postmenstrual age; BSID, Bayley Scale of Infantile Development; BW, birth weight; MDI, mental developmental index; PDI, psychomotor index.

*The numbers following "AA" or "lipid" are the doses expressed as g/kg/day otherwise unspecified. The numbers in parenthesis following the AA dose represent the starting and target doses of AA, respectively, at the specific day after birth.

Go to Top