Blood Phenylalanine Levels in Patients with Phenylketonuria from Europe Between 2012 and 2018: Is It a Changing Landscape?

Overview

Journal Nutrients

Date 2024 Jul 13

PMID 38999811

Authors

Alex Pinto

Kirsten Ahring

Manuela Ferreira Almeida

Catherine Ashmore

Amaya Belanger-Quintana

Alberto Burlina

Turgay Coskun

Anne Daly

Esther van Dam

Ali Dursun

Sharon Evans

Francois Feillet

Maria Gizewska

Hulya Gokmen-Ozel

Mary Hickson

Yteke Hoekstra

Fatma Ilgaz

Richard Jackson

Alicja Lesniak

Christian Loro

Katarzyna Malicka

Michal Patalan

Julio Cesar Rocha

Serap Sivri

Iris Rodenburg

Francjan van Spronsen

Kamilla Straczek

Aysegul Tokatli

Anita MacDonald

Affiliations

Soon will be listed here.

Abstract

Background: In 2011, a European phenylketonuria (PKU) survey reported that the blood phenylalanine (Phe) levels were well controlled in early life but deteriorated with age. Other studies have shown similar results across the globe. Different target blood Phe levels have been used throughout the years, and, in 2017, the European PKU guidelines defined new targets for blood Phe levels. This study aimed to evaluate blood Phe control in patients with PKU across Europe.

Methods: nine centres managing PKU in Europe and Turkey participated. Data were collected retrospectively from medical and dietetic records between 2012 and 2018 on blood Phe levels, PKU severity, and medications.

Results: A total of 1323 patients (age range:1-57, 51% male) participated. Patient numbers ranged from 59 to 320 in each centre. The most common phenotype was classical PKU ( = 625, 48%), followed by mild PKU ( = 357, 27%) and hyperphenylalaninemia (HPA) ( = 325, 25%). The mean percentage of blood Phe levels within the target range ranged from 65 ± 54% to 88 ± 49% for all centres. The percentage of Phe levels within the target range declined with increasing age (<2 years: 89%; 2-5 years: 84%; 6-12 years: 73%; 13-18 years: 85%; 19-30 years: 64%; 31-40 years: 59%; and ≥41 years: 40%). The mean blood Phe levels were significantly lower and the percentage within the target range was significantly higher ( < 0.001) in patients with HPA (290 ± 325 μmol/L; 96 ± 24%) and mild PKU (365 ± 224 μmol/L; 77 ± 36%) compared to classical PKU (458 ± 350 μmol/L, 54 ± 46%). There was no difference between males and females in the mean blood Phe levels ( = 0.939), but the percentage of Phe levels within the target range was higher in females among school-age children (6-12 years; 83% in females vs. 78% in males; = 0.005), adolescents (13-18 years; 62% in females vs. 59% in males; = 0.034) and adults (31-40 years; 65% in females vs. 41% in males; < 0.001 and >41 years; 43% in females vs. 28% in males; < 0.001). Patients treated with sapropterin ( = 222) had statistically significantly lower Phe levels compared to diet-only-treated patients (mean 391 ± 334 μmol/L; percentage within target 84 ± 39% vs. 406 ± 334 μmol/L; 73 ± 41%; < 0.001), although a blood Phe mean difference of 15 µmol/L may not be clinically relevant. An increased frequency of blood Phe monitoring was associated with better metabolic control ( < 0.05). The mean blood Phe (% Phe levels within target) from blood Phe samples collected weekly was 271 ± 204 μmol/L, (81 ± 33%); for once every 2 weeks, it was 376 ± 262 μmol/L, (78 ± 42%); for once every 4 weeks, it was 426 ± 282 μmol/L, (71 ± 50%); and less than monthly samples, it was 534 ± 468 μmol/L, (70 ± 58%).

Conclusions: Overall, blood Phe control deteriorated with age. A higher frequency of blood sampling was associated with better blood Phe control with less variability. The severity of PKU and the available treatments and resources may impact the blood Phe control achieved by each treatment centre.

Citing Articles

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Genotype-Phenotype Correlation in a Large Cohort of Eastern Sicilian Patients Affected by Phenylketonuria: Newborn Screening Program, Clinical Features, and Follow-Up.

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Longitudinal Dietary Intake Data in Patients with Phenylketonuria from Europe: The Impact of Age and Phenylketonuria Severity.

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