Omega-3 Long-Chain Polyunsaturated Fatty Acids in Older Children

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Abbreviations: AA, Arachidonic acid, DHA, Docosahexaenoic acid, EPA, Eicosapentaenoic acid, LC-PUFA, Long-chain polyunsaturated fatty acids, PKU, Phenlketonuria, VEP, Visual evoked potential

Phenylketonuria (PKU), the most prevalent inborn error of metabolism, is usually caused by low hepatic activity of phenylalanine hydroxylase, the enzyme that catalyzes conversion of phenylalanine to tyrosine.¹ It is characterized by a high plasma phenylalanine concentration and, in the absence of adequate tyrosine intake, a low plasma tyrosine concentration. Management of patients with PKU includes early detection, primarily by mandatory neonatal screening programs, followed by a low protein diet supplemented with a low-phenylalanine or phenylalanine-free formula. Frequent monitoring and appropriate dietary changes in response to this monitoring are necessary to maintain plasma phenylalanine and tyrosine concentrations within the desired range.

Growth and development of infants and children with PKU who are treated as aforementioned do not differ appreciably from population norms. However, the IQ of treated children with PKU is somewhat lower than that of their unaffected siblings.² These children also perform less well in school than their unaffected siblings, they tend to exhibit more behavioral problems, and they have problems concentrating. However, current outcomes of infants and children with PKU are far superior to the severe psychomotor retardation that occurs without treatment.

A major question concerns the extent to which the residual developmental deficits of optimally treated infants and children with PKU are an inevitable consequence of the condition. A study reported by Beblo et al³ in this issue of the Journal suggests that at least some of the residual deficits can be further reduced or perhaps abolished by dietary supplementation with fish oil, a rich source of omega-3 long-chain polyunsaturated fatty acids (LC-PUFA), particularly eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA). The latter fatty acid has received considerable attention in the past 20 years. It is present in high concentrations in the developing brain and retina, and failure to provide a dietary source of this fatty acid results in low plasma, erythrocyte, and brain lipid levels of DHA.⁴ Many studies also show that failure to provide a dietary source of DHA adversely affects cognitive and visual development.⁴ Thus, most infant formulas throughout the world now contain DHA or this fatty acid plus arachidonic acid (AA). The amounts present reflect the content of these fatty acids in human milk. Although most studies have involved short periods of supplementation during early life, usually for only a few months and almost never beyond the first year of life, these supplemented formulas appear to be safe.

Despite the rate of deposition of DHA in the developing brain not slowing appreciably until well after a year of age,⁵ little is known about the need for a dietary source of this fatty acid in children older than 12 to 18 months. This is unfortunate, because the endogenous production of DHA from its precursor, alpha-linolenic acid, is thought to be inefficient, and intake of preformed DHA (eg, fish) by most children (and many adults) is quite low.

Beblo et al studied 1- to 11-year-old (mean, 6.3 ± 0.6 years) children with PKU who had been in good metabolic control for at least 6 months and a control group of unaffected age- and sex-matched children. After determining plasma phospholipid fatty acid pattern and administering the motometric Rostock Oseretzki Scale, a standardized scale that assesses coordination and fine motor skills of children between 4 and 11 years old, the patients received fish oil (approximately 15 mg/kg/d of DHA and 22.5 mg/kg/d of EPA) for 90 days, after which the baseline studies were repeated. Baseline plasma phospholipid DHA content of both the children with PKU and the control subjects was low but not different from that of a reference population from the same geographic region. Fish oil supplementation of the children with PKU resulted in a 3-fold increase in plasma phospholipid DHA content, an 8-fold increase in plasma phospholipid EPA content, and a 25% decrease in plasma phospholipid AA content. Baseline performance assessed with the standardized test of coordination and fine motor skills was within the reference range in both patients and control subjects, but performance of the children in the control group was better than that of the children with PKU. However, after fish oil supplementation, performance of children with PKU was markedly improved, whereas the performance of control subjects (who did not receive fish oil or have plasma phospholipid fatty acids repeated) was not different from baseline.

These investigators⁶ and other groups⁷ have previously shown that omega-3 LC-PUFA supplementation of patients with PKU lowers visual evoked potential (VEP) latency and that the magnitude of decrease in latency is associated with the observed increase in DHA content of erythrocyte lipids. Other studies have shown that the difference in VEP latency is not apparent 3 years after terminating supplementation,⁸ suggesting that a continuous supply of omega-3 LC-PUFA may be required. In contrast, children with PKU who were breastfed (and, hence, received DHA) for as long as 6 weeks before beginning dietary therapy had a 12.9-point higher IQ at 9 years of age (after adjustment for social class and maternal education) than infants who were formula-fed for the same period.⁹ Metabolic control of the 2 groups after diagnosis and beginning dietary therapy did not differ.

In toto, the study of Beblo et al³ adds considerably to an existing body of data suggesting that omega-3 LC-PUFA may be conditionally essential for infants and children with PKU. This, presumably, is because the usual PKU diet is low in protein and, hence, low in the common dietary sources of omega-3 LC-PUFA (eg, fish, meat, eggs). This also appears to be true for other nutrients; for example, formulas for patients with PKU are supplemented with several essential trace minerals and vitamins that have been shown to be low in low protein diets or poorly available from these diets.

The improvement of older children with PKU because of omega-3 LC-PUFA supplementation, without changes in plasma phenylalanine concentration, suggests that still other groups might benefit from dietary omega-3 LC-PUFA. Certainly, the brain continues to grow well beyond infancy,⁵ and there likely is considerable turnover of brain components, including DHA, after adult size is reached; thus, there may be benefits of omega-3 LC-PUFA supplementation, not only during infancy and early childhood, but also, perhaps, during adolescence and adulthood.

Currently, evidence that children with PKU might benefit from omega-3 LC-PUFA supplementation, perhaps as a component of their low phenylalanine formula, is reasonably strong. However, whether this supplement should be EPA, DHA, or perhaps both, as studied by Beblo et al,³ is not clear. The amount of these fatty acids that should be provided also is not clear. An 8% increase in plasma phospholipid EPA content, as reported by Beblo et al,³ seems somewhat excessive. Further, considering the 27% decrease in plasma phospholipid AA observed by Beblo et al,³ the supplement perhaps should also include omega-6 LC-PUFA.

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References 

1. Scriver CR, Kaufman S, Eisensmith RC, Woo SLC. The hyperphenylalaninemias. In:  Scriver RC,  Beaudet AL,  Sly WS,  Valle D editor. The metabolic and molecular basis of inherited disease. 7th ed.. New York: McGraw-Hill; 1998;p. 1015–1075
   • View In Article
2. Schmidt E, Burgard P, Rupp A. Effects of concurrent phenylalanine levels on sustained attention and calculation speed in patients treated early for phenylketonuria. Eur J Pediatr. 1996;155(Suppl 1):S82–S86
   • View In Article
   • CrossRef
3. Beblo S, Reinhardt H, Demmelmair H, Muntau A, Koletzko . Effect of fish oil supplementation on fatty acid status, coordination and fine motor skills in children with phenylketonuria. J Pediatr. 2007;150:479–484
   • View In Article
   • Abstract
   • Full Text
   • Full-Text PDF (125 KB)
   • CrossRef
4. Heird WC, Lapillonne A. The role of essential fatty acids in development. Ann Rev Nutr. 2005;25:549–571
   • View In Article
5. Martinez M, Mougan I. Fatty acid composition of human brain phospholipids during normal development. J Neurochem. 1998;71:2528–2533
   • View In Article
   • MEDLINE
   • CrossRef
6. Beblo S, Reinhardt H, Muntau AC, Mueller-Felber W, Roscher AA, Koletzko B. Fish oil supplementation improves visual evoked potentials in children with phenylketonuria. Neurology. 2001;57:1488–1491
   • View In Article
   • MEDLINE
7. Agostoni C, Massetto N, Biasucci G, Rottoli A, Bonvissuto M, Bruzzese MG, et al. Effects of long-chain polyunsaturated fatty acid supplementation on fatty acid status and visual function in treated children with hyperphenylalaninemia. J Pediatr. 2000;137:504–509
   • View In Article
   • Abstract
   • Full Text
   • Full-Text PDF (83 KB)
   • CrossRef
8. Agostoni C, Verduci E, Massetto N, Fiori L, Radaelli G, Riva E, et al. Long-term effects of long-chain polyunsaturated fats in hyperphenylalaninemic children. Arch Dis Child. 2003;88:582–583
   • View In Article
   • CrossRef
9. Riva E, Agostoni C, Biasucci G, Trojan S, Luotti D, Fiori L, et al. Early breastfeeding is linked to higher intelligence quotient scores in dietary treated phenylketonuric children. Acta Paediatr. 1996;85:56–58
   • View In Article
   • MEDLINE
   • CrossRef