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01-10-2018 | Original Article

The influence of blood phenylalanine levels on neurocognitive function in adult PKU patients

Authors: A. Bartus, F. Palasti, E. Juhasz, E. Kiss, E. Simonova, Cs. Sumanszki, P. Reismann

Published in: Metabolic Brain Disease | Issue 5/2018

Abstract

It is well known that hyperphenylalaninemia caused by phenylketonuria (PKU) negatively influences cognitive performance. Several tests have been used to study these functions. Until now, no universal, optimal tool has been developed for detecting PKU-caused brain dysfunctions. Using computerized neuropsychological tests during daily routine would be helpful for screening subclinical brain deficits in adult PKU patients. In a monocentric, cross-sectional study, adult patients with PKU (n = 46; median age = 29.5 years; female/male ratio = 21/25) were tested with the computerized Cambridge Cognition (CANTAB) test measuring neurocognitive functions. Patients were divided into two groups: The “on diet” group included patients whose blood Phe-level was under 600 μmol/l (n = 20), and the “loose diet” group included patients whose blood Phe-level was above 600 μmol/l (n = 26) at the examination time. The results of the PKU-affected individuals were compared with a healthy control group (n = 31; median age = 25 years; female/male ratio = 11/20). Compared with the control group, PKU patients had significantly worse test results in memory, problem-solving skills, and strategy. However, there were no significant differences in response speed or initial thinking time. There was no correlation between the blood Phe-level, tyrosine (Tyr)-level or Phe/Tyr ratio and the different cognitive test results. There were no significant differences in test results between the two PKU subgroups. Several cognitive functions measured by CANTAB are negatively influenced by hyperphenylalaninemia in adult PKU patients. However, response speed and initial thinking time were not impaired as seriously as other functions. Patients with lower Phe-levels failed to achieve better test results than patients whose Phe-levels were notably elevated.

Albrecht J, Garbade SF, Burgard P (2009) Neuropsychological speed tests and blood phenylalanine levels in patients with phenylketonuria. A meta-analysis. Neurosci Behav Rev 33:414–421CrossRef

Anderson PJ, Wood SJ, Francis DE, Coleman L, Anderson V, Boneh A (2007) Are neuropsychological impairments in children with early-treated phenylketonuria (PKU) related to white matter abnormalities or elevated phenylalanine levels? Dev Neuropsychol 32:645–668CrossRefPubMed

Bik-Multanowski M, Pietrzyk JJ (2011) Use of computerized neuropsychological tests and of nuclear magnetic resonance spectroscopy in clinical assessment of adult patients with phenylketonuria. Przegl Lek 68:127–131PubMed

Bik-Multanowski M, Pietrzyk JJ, Mozrzymas R (2011) Routine use of CANTAB system for detection of neuropsychological deficits in patients with PKU. Mol Genet Metab 102:210–213CrossRefPubMed

Blau N, Erlandsen H (2004) The metabolic and molecular bases of tetrahydrobiopterin-responsive phenylalanine hydroxylase deficiency. Mol Genet Metab 82:101–111CrossRefPubMed

Burgard P, Ullrich K, Ballhausen D, Hennermann JB, Hollak CEM, Langeveld M, Karall D, Konstantopoulou V, Maier EM, Lang F, Lachmann R, Murphy E, Garbade S, Hoffmann GF, Kölker S, Lindner M, Zschocke J (2017) Issues with European guidelines for phenylketonuria. Lancet Diabetes Endocrionol 5:681–683CrossRef

Camp KM, Parisi M, Acosta P, Berry G, Bilder D, Blau N, Bodamer O et al (2014) Phenylketonuria scientific review conference: state of the science and future research needs. Mol Genet Metab 112:87–122CrossRefPubMed

Channon S, Mockler C, Lee P (2005) Executive functioning and speed of processing in phenylketonuria. Neuropsychology 19:679–686CrossRefPubMed

Christ SE, Huijbregts SC, de Sonneville LM, White DA (2010) Executive function in early-treated phenylketonuria: profile and underlying mechanisms. Mol Genet Metab 99(Suppl 1):S22–S32CrossRefPubMed

Di Ciommo V, Forcella E, Cotugno G (2012) Living with phenylketonuria from the point of view of children, adolescents, and young adults: a qualitative study. J Dev Behav Pediatr 33:229–235CrossRefPubMed

Feldmann R, Denecke M, Grenzebach M, Weglage J (2005) Frontal lobe dependent functions in treated phenylketonuria: blood phenylalanine concentrations and long-term deficits in adolescents and young adults. J Inherit Metab Dis 28:445–455CrossRefPubMed

Griffiths P, Smith C, Harvie A (1997) Transitory hyperphenylalaninaemia in children with continuously treated phenylketonuria. Am J Ment Retard 102:27–36CrossRefPubMed

Jahja R, Huijbregts S, De Sonneville L, Van der Meere J, Bosch A, Hollak C, Rubio-Gozalbo E et al (2013) Mental health and social functioning in early-treated phenylketonuria: the PKU-COBESO study. Mol Genet Metab 110:S57–S61CrossRefPubMed

Jahja R, Huijbregts SC, de Sonneville LM, van der Meere JJ, van Spronsen FJ (2014) Neurocognitive evidence for revision of treatment targets and guidelines for phenylketonuria. J Pediatr 164:895–899CrossRefPubMed

Jahja R, Huijbregts SCJ, de Sonneville LMJ, van der Meere JJ, Legemaat AM, Bosch AM, Hollak CEM et al (2017a) Cognitive profile an mental health in adult phenylketonuria: a PKU-COVESO study. Nuropsychology 31:437–447CrossRef

Jahja R, van Spronsen FJ, de Sonneville LMJ, van der Meere JJ, Bosch AM, Hollak CEM et al (2017b) Long-term follow-up of cognition and mental health in adult phenylketonuria: a PKU-COBESO study. Behav Genet 47:486–497CrossRefPubMedPubMedCentral

Janos AL, Grange DK, Steiner RD, White DA (2012) Processing speed and executive abilities in children with phenylketonuria. Neuropsychology 26:735–743CrossRefPubMedPubMedCentral

Koch R, Burton B, Hoganson G, Peterson R, Rhead W, Rouse B, Scott R et al (2002) Phenylketonuria in adulthood: a collaborative study. J Inherit Metab Dis 25:333–346CrossRefPubMed

Moyle JJ, Fox AM, Bynevelt M, Arthur M, Burnett JR (2007a) A neuropsychological profile of off-diet adults with phenylketonuria. J Clin Exp Neuropsychol 29:436–441CrossRefPubMed

Moyle JJ, Fox AM, Arthur M, Bynevelt M, Burnett JR (2007b) Meta-analysis of neuropsychological symptoms of adolesents and adults with PKU. Neuropsychol Rev 17:91–101CrossRefPubMed

Nardecchia F, Manti F, Chiarotti F, Carducci C, Carducci C, Leuzzi V (2015) Neurocognitive and neuroimaging outcome of early treated young adult PKU patients: a longitudinal study. Mol Genet Metab 115:84–90CrossRefPubMed

Perri RL, Berchicci M, Spinelli D, Di Russo F (2014) Individual differences in response speed and accuracy are associated to specific brain activities of two interacting systems. Front Behav Neurosci 8:251PubMedPubMedCentral

Scriver CR, Beaudet AL, Sly WS, Valle D (1996) The metabolic and molecular bases of inherited disease, 7th edn. McGraw–Hill, New York, pp 1015–1075

Sharman R, Sullivan K, Young R, McGill J (2015) Executive function in adolescents with PKU and their siblings: associations with biochemistry. Mol Genet Metab Rep 4:87–88CrossRefPubMedPubMedCentral

van Spronsen FJ, van Wegberg AM, Ahring K, Bélanger-Quintana A, Blau N, Bosch AM, Burlina A, Campistol J, Feillet F, Gizewska M, Huijbregts SC, Kearney S, Leuzzi V, Maillot F, Muntau AC, Trefs FK, van Rijn M, Walter JH, MacDonald A (2017) Key European guidelines for the diagnosis and management of patients with phenylketonuria. Lancet Diabetes Endocrinol 5:743–756CrossRefPubMed

Vockley J, Andersson HC, Antshel KM, Braverman NE, Burton BK, Frazier DM, Mitchell J, Smith WE, Thompson BH, Berry SA, American College of Medical Genetics and Genomics Therapeutics Committee (2014) Phenylalanine hydroxylase deficiency: diagnosis and management guideline. Genet Med 16:188–200CrossRefPubMed

Waisbren SE, Schnell RR, Levy HL (1980) Diet termination in children with phenylketonuria: a review of psychological assessments used to determine outcome. J Inherit Metab Dis 3:149–153CrossRefPubMed

Weglage J, Pietsch M, Feldmann R, Koch HG, Zschocke J, Hoffmann G, Muntau-Heger A, Denecke J, Guldberg P, Güttler F, Möller H, Wendel U, Ullrich K, Harms E (2001) Normal clinical outcoma in untreated subjects with mild hyperphenylalaninemia. Pediatr Res 49:532–536CrossRefPubMed

Title: The influence of blood phenylalanine levels on neurocognitive function in adult PKU patients
Authors: A. Bartus
F. Palasti
E. Juhasz
E. Kiss
E. Simonova
Cs. Sumanszki
P. Reismann
Publication date: 01-10-2018
Publisher: Springer US
Published in: Metabolic Brain Disease / Issue 5/2018
Print ISSN: 0885-7490
Electronic ISSN: 1573-7365
DOI: https://doi.org/10.1007/s11011-018-0267-6

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The influence of blood phenylalanine levels on neurocognitive function in adult PKU patients

Abstract

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Abstract

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