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OBJECTIVES@#To retrospectively analyze the variation and characteristics of phenylalanine hydroxylase (PAH) gene, and to observe the long-term treatment effect and follow-up of newborns with PAH deficiency.@*METHODS@#Clinical data, treatment and follow-up results of 198 patients with PAH deficiency diagnosed by newborn screening in Jinan from 1996 to 2021 were collected. The genetic analysis of 55 patients with PAH deficiency diagnosed by newborn screening in Jinan and 213 patients referred from the surrounding areas of Jinan were summarized. Gene variations were checked by a customized Panel gene detection method. Blood phenylalanine-concentration and physical development indicators including height and weight were regularly monitored. Intellectual development was assessed using a neuropsychological development scale for patients aged 0-6 years and academic performance, and brain injury in patients was assessed using brain magnetic resonance imaging.@*RESULTS@#c.728G>A, c.158G>A, c.721C>T, c.1068C>A, c.611A>G variations were common in PAH gene. The genotype of c.158G>A variation is compound heterozygous variation, with mainly a mild hyperpheny-lalaninemia. 168 patients with PAH deficiency who were followed-up regularly had normal physical development without dwarfism or malnutrition. Among the 33 preschool patients who underwent mental development assessment, 2 were mentally retarded and the initial treatment age was older than 6 months. Nine patients with an average age of (17.13±2.42) years completed brain magnetic resonance imaging, one case was normal, and 8 cases were abnormal. There were patchy or patchy hyperintense foci near the bilateral lateral ventricles on T2WI, and the intellectual development was normal. Compared with the other eight patients, the blood phenylalanine concentration of the normal child was better and stably controlled within the ideal range.@*CONCLUSIONS@#c.728G>A, c.158G>A, c.721C>T, c.1068C>A, c.611A>G variations were common in PAH gene. After standardized treatment, most patients with PAH deficiency diagnosed by screening can obtain normal growth and intellectual development in adolescence, but there are different degrees of organic lesions in the cerebral white matter.
Subject(s)
Child , Child, Preschool , Adolescent , Humans , Infant, Newborn , Young Adult , Adult , Neonatal Screening , Follow-Up Studies , Retrospective Studies , Phenylketonurias/genetics , Phenylalanine Hydroxylase/genetics , Phenylalanine/therapeutic use , MutationABSTRACT
Objective:To screen new drugs for treatment of phenylalanine hydroxylase deficiency.Methods:From October 2019 to October 2020, virtual drug screening was performed in Center of Genetic Medicine, Nanjing Maternity and Child Health Care Hospital, Women's Hospital of Nanjing Medical University computer according to the characteristics of the binding ability of phenylalanine hydroxylase to drug spatial structure. Ten candidate drugs were screened from the FDA drug library (including 2 697 kinds of active pharmaceutical ingredients). A eukaryotic expression system was used to determine the effects of drugs on the activity of phenylalanine hydroxylase at the molecular level. Drug-sensitive mutants were screened.Results:Among the 10 candidate drugs, neoplasm hydrochloride, fluocinonide acetate and risperidone increased 23% [ t = 18.21, P < 0.001, vs. non-drug-treated phenylalanine hydroxylase group (i.e., only solvent and no drug added to the reaction system)], 21% ( t = 3.44, P < 0.05, vs. non-drug-treated phenylalanine hydroxylase group), 31% ( t = 19.57, P < 0.001, vs. non-drug-treated phenylalanine hydroxylase group) of the activity of phenylalanine hydroxylase. The remaining drugs exhibited weak even inhibitory effects on the activity of phenylalanine hydroxylase. 25% of p.D101N mutant could be activated by risperidone ( t = 15.86, P < 0.001, vs. non-drug-treated p.D101N mutant group). Conclusion:Neoplasm hydrochloride, fluocinonide acetate and risperidone can be used as potential therapeutic drugs for phenylalanine hydroxylase deficiency, and p.D101N mutant can be used as the drug-sensitive mutation site.
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Objective To study the characteristics of hyperphenylalaninemia (HPA) and the differences in blood and urine metabolic index and their correlation.Methods A total of 137 patients with HPA diagnosed by the Pediatric Inherit Metabolism and Endocrine Department,Guangdong Women and Children's Hospital,Guangzhou Medical University from January 2014 to June 2017,were enrolled.Tandem mass spectrometry (MS/MS),gas chromatography/ mass spectrometry (GC-MS) and high performance liquid chromatography (HPLC) were used to analyze the concentration of blood and urine metabolites in children,and the patients were divided into different groups according to the drug load test of tetrahydrobiopterin (BH4) and dihydrobiopterindine reductase (DHPR) deficiency.The HPA metabolite analysis of horizontal concentration by statistical differences and correlation analysis were performed.Results Among the 137 cases of HPA,there were 101 cases (73.7%) of phenylalanine hydroxylase deficiency (PAH),and among them 21 cases (15.3%) were classic phenylketonuria (PKU),37 cases were mild PKU (27.0%),43 cases (31.4%) wcrc mild HPA.Thcrc were 22 cases (16.1%) with BH4 reaction,and 79 cases (57.7%) of non-reactive type.Besides,there were 36 cases (26.3%) of tetrahydrobiopterin deficiency (BH4 D),of which 6-pyruvoyl tetrahydropterin synthase deficiency (PTPS) in 34 cases (24.8%) and dihydrobiopterindine reductase deficiency (DHPR) in 2 cases (1.5%).Urinary phenylacetic acid (r =0.673,P < 0.01),phenyllactic acid (r =0.736,P < 0.01),phenylpyruvic acid (r =0.642,P < 0.01) were significantly correlated with blood phenylalanine (Phe) concentration,and the neopterin (N) (r =0.442,P < 0.01) and biopterin (B) (r =0.398,P < 0.01) had low correlation.Urinary phenylacetic acid,phenyllactic acid and phenylpyruvic acid had no correlation with urinary pterin.There were significant differences among PTPS deficiency group,BH4 response type,and non-reactive type(all P < 0.05),but no significant difference between the BH4 reaction type and the non-reactive group (P > 0.05).Conclusions Through the analysis of the different types of HPA metabolic profiles,it can help to master the incidence and characteristics in the region,within a certain concentration range of blood Phe,the phenylacetic acid,phenyllactic acid,phenylpyruvic acid should not be tested by GC-MS alone.Uterine erythropoietin analysis of BH4D classification and identification of BH4 reaction,non-reactive PKU have a supporting role,so master the metabolic index of various types of concentration and relevance of HPA,it can provide basis for early diagnosis,accurate treatment and follow-up.
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Abstract Nearly half of all patients diagnosed with phenylalanine hydroxylase (PAH) deficiency, also known as phenylketonuria, are lost to follow-up (LTFU); most are adults who stopped attending clinic after the age of 18 years. To understand why adult patients with PAH deficiency disengage from their clinic, a focus group of 8 adults with PAH deficiency who had been LTFU for 2 or more years was held in March 2016. Ten clinicians observed the focus group and discussed strategies for successfully reengaging adult patients and encouraging lifelong management of PAH deficiency. Four strategies were proposed: (1) create a safe, supportive environment, (2) acknowledge patients as partners in their care, (3) develop individualized management plans, and (4) provide patients with additional resources. These strategies provide a framework to motivate change in clinical practice to meet the unique needs of adults with PAH deficiency.
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Abstract Phenylketonuria (PKU) is caused by a deficient activity of enzyme phenylalanine (Phe) hydroxylase, which results in high Phe blood concentration, which is toxic to the central nervous system. The fundamental purpose of nutritional treatment is to reduce and maintain blood Phe between 2 mg/dL (120 µmol/L) and 6 mg/dL (360 µmol/L) in order to prevent neuropathogenic complications. At the same time, nutrition support must provide enough energy and nutrients to promote normal growth and development and also to avoid vitamin and mineral deficiencies. Phenylketonuria treatment must be maintained long-life and its adherence must be frequently assessed. The amount of Phe required by patients with PKU varies throughout life and must be adjusted according to individual tolerance, residual phenylalanine hydroxylase enzymatic activity, age, sex, growth rate, protein intake, and nutritional and biochemical status among others. Treatment must be done by trained personnel. It is necessary to unify treatment criteria and further research must be done.