Newborn phenylalanine/tyrosine metabolism. Implications for screening for phenylketonuria

Controversy over the sensitivity of newborn screening for phenylketonuria (PKU) has recently led to the specific recommendation that infants discharged within the first 24 hours of life be routinely retested at 1 to 2 weeks of age. To address this controversy, data from cord blood samples, phenylalanine (Phe) tolerance tests at 3 days of age, and sequential plasma Phe determinations in six siblings of known cases of PKU or hyperphenylalaninemia were analyzed, along with data from the literature. These analyses showed that normal and probably heterozygous infants decrease their Phe concentrations with age, while infants with PKU or PKU variants increase their Phe concentrations with age but at varying rates. Predictive equations showed that the sensitivity of the screening test rapidly increases with age, so that the usual critical value of 4 mg/dL is satisfactory for suspecting PKU after 18 hours of age. A critical value of 3 mg/dL would be equally satisfactory at any age, if the Guthrie test were appropriately modified to include a 3-mg/dL standard.     

四氢生物蝶呤反应性苯丙氨酸羟化酶缺乏症

目的：四氢生物蝶呤(BH4)可以使BH4缺乏症病人的血液苯丙氨酸水平正常化,但是对苯丙酮酸尿症(PKU)病人无效。最近在新生儿PKU筛查中发现了对BH4有反应的轻度PKU患者。本研究将探讨BH4和苯丙氨酸羟化酶(PAH)基因突变在对BH4有反应的轻度PKU和轻度高苯丙酸血症(HPA)患者中的作用。方法：对经新生儿PKU筛查中发现的生物蝶呤代谢正常的轻度HPA患者,进行单次(10mg/kg)、4次、1周[20 mg/(kg·d)]的BH4口服负荷试验及长期BH4治疗,评估其对BH4口服负荷试验的反应性。结果：在单剂量BH4口服负荷试验中,典型PKU患者的血苯丙氨酸水平没有降低。在单剂量BH4口服负荷试验中血苯丙氨酸水平下降超过20%的患者,在4次BH4口服负荷试验中下降亦超过20%。1周BH4负荷试验确认在单剂量和4次BH4负荷试验中表现出弱反应性的病人对BH4有反应。许多患轻度PKU和轻度HPA且有R241C基因位点的病人,都对BH4治疗有反应。在无BH4反应性的典型PKU病人中未发现R241C、P407S和A373T基因突变。结论：1周BH4负荷试验用于诊断BH4反应性PAH缺乏症最为有效。等位基因R241C、P407S和A373T与轻度HPA和轻度PKU病人具有H4反应性有关。BH4治疗是针对轻度HPA和轻度PKU的一种新颖、有效的药物治疗,有望代替限制苯丙氨酸饮食的方法。     

In vivo studies of phenylalanine hydroxylase by phenylalanine breath test: diagnosis of tetrahydrobiopterin-responsive phenylalanine hydroxylase deficiency

Tetrahydrobiopterin (BH4)-responsive phenylalanine hydroxylase (PAH) deficiency is characterized by reduction of blood phenylalanine level after a BH4-loading test. Most cases of BH4-responsive PAH deficiency include mild phenylketonuria (PKU) or mild hyperphenylalaninemia (HPA), but not all patients with mild PKU respond to BH4. We performed the phenylalanine breath test as reliable method to determine the BH4 responsiveness. Phenylalanine breath test quantitatively measures the conversion of L-[1-13C] phenylalanine to 13CO2 and is a noninvasive and rapid test. Twenty Japanese patients with HPA were examined with a dose of 10 mg/kg of 13C-phenylalanine with or without a dose of 10 mg . kg(-1) . d(-1) of BH4 for 3 d. The phenylalanine breath test [cumulative recovery rate (CRR)] could distinguish control subjects (15.4 +/- 1.5%); heterozygotes (10.3 +/- 1.0%); and mild HPA (2.74%), mild PKU (1.13 +/- 0.14%), and classical PKU patients (0.29 +/- 0.14%). The genotypes in mild PKU cases were compound heterozygotes with mild (L52S, R241C, R408Q) and severe mutations, whereas a mild HPA case was homozygote of R241C. CRR correlated inversely with pretreatment phenylalanine levels, indicating the gene dosage effects on PKU. BH4 loading increased CRR from 1.13 +/- 0.14 to 2.95 +/- 1.14% (2.6-fold) in mild PKU and from 2.74 to 7.22% (2.6-fold) in mild HPA. A CRR of 5 to 6% reflected maintenance of appropriate serum phenylalanine level. The phenylalanine breath test is useful for the diagnosis of BH4-responsive PAH deficiency and determination of the optimal dosage of BH4 without increasing blood phenylalanine level.     

MILD AND SEVERE PKU. COMPARATIVE STUDIES IN TWO INFANTS

Two infants with hyperphenylalaninemia first recognized at the age of 5 days were studied. One of the patients was a case of classical severe PKU. The other patient, on an unrestricted diet, showed only a slow rise in the plasma phenylalanine level amounting to 16 mg/100 ml at 3 weeks of age and had no phenylpyruvic aciduria. The plasma phenylalanine levels of the two infants were determined during fasting, after feeding and after intravenous phenylalanine loading. The results obtained did not reveal any significant difference in the phenylalanine turn over between the two infants.     

Hyperphenylalaninaemia of various types among three-quarters of a million neonates tested in a screening programme.

A total of 795 382 infants born in north London was screened for phenylketonuria using the Guthrie test between October 1969 and December 1978. During this period it became recognised that phenylketonuria is not a single disease entity but one that encompasses a number of disorders of differing clinical and biochemical severity. The overall incidence of persistent hyperphenylalaninaemia was of the order of 7 per 100 000 births (or 1 in 15 000) and all the early treated patients made normal developmental progress. During the study there was an appreciable fall in the incidence of uncomplicated transient hyperphenylalaninaemia with or without tyrosinaemia. This reduction coincided with the change in infant feeding practice in the UK which led to lower intakes of protein and phenylalanine. It was concluded that any infant found to have a persistent blood phenylalanine concentration of 240 mumol/1 (4 mg/100 ml) or greater should be followed closely.     

Newborn phenylketonuria (PKU) Guthrie (BIA) screening and early hospital discharge

Recent policies of early discharge of postpartum mothers and their infants has raised concerns of possible decreased sensitivity in Guthrie bacterial inhibition assay (BIA) phenylketonuria (PKU) screening resulting in missed cases. In order to assess the potential impact of early discharge from hospital on neonatal screening for PKU and its variants, we performed 18 standard BIA screening tests on 11 newborn infants with the disease. Blood spot samples were collected from 1 to 24 h after birth and were analyzed at the Ontario Ministry of Health newborn screening laboratory according to the routine screening protocol. Except for one 4-hour postnatal sample from an infant with ‘non-PKU mild hyperphenylalaninemia’ (MHP) all blood samples showed phenylalanine levels ≥240 μmol/l, irrespective of the age of the baby. During our 29 year experience with neonatal PKU screening (3.9 million infants tested), employing a cutoff blood phenylalanine of 240 μmol/l in blood spots obtained at ≥24 h of age, only two biological false negative (one confirmed) tests were discovered in infants subsequently shown to have classical PKU; another three false negative tests were discovered in sibs of infants with MHP. The sensitivity of the screening test was 99.2% for infants with classical and mild PKU. Ascertainment of patients with MHP is unknown and is very likely incomplete. Over a 3-year period (1992–1994) the specificity of the test was 99.9% for those screened after 24 h. The positive predictive value was 12.8%. Although early discharge may have an impact on other screened diseases, we conclude, from our studies, that early discharge may not affect the detection of infants with classical and mild (atypical) PKU, but would probably increase the number of infants with MHP missed using the BIA and a cutoff level of 240 μmol/l. Because of our experience and that of others, we recommend that neonates be at least 12 h of age before initial BIA PKU screening be carried out. To confirm this recommendation further prospective studies should be initiated.     

Atypical cases of phenylketonuria

Conclusion Neonatal HPA can be caused by deficiency of PAH or of its cofactor. At present, conventional methods are not able to delineate the molecular basis of the mutations in PKU patients. DNA analysis might in future visualize the different genotypes, but might not solve the problem of therapeutic decision.All infants with HPA should be screened for THB deficiency. Diagnostic tools are now available for the recognition of these variants among hyperphenylalaninemic infants. The most important question-which infants can achieve normal development if treated early-remains tobe answered. Efforts have to be directed toward better characterization of individual residual capacity to synthesize THB and toward and definition of protocols for the follow-up of neurotransmitter replacement therapy.Abbreviations PKU phenylketonuria - HPA hyperphenylalaninemia - PAH phenylalanine hydroxylase - DHPR dihydropteridine reductase - BS biopterin synthetase - THB tetrahydrobiopterin - GTP guanosine triphosphate - GTP-ch GTP-cyclohydrolase - N/B ratio neopterin/biopterin ratio     

Long-term treatment and diagnosis of tetrahydrobiopterin-responsive hyperphenylalaninemia with a mutant phenylalanine hydroxylase gene

A novel therapeutic strategy for phenylketonuria (PKU) has been initiated in Japan. A total of 12 patients who met the criteria for tetrahydrobiopterin (BH(4))-responsive hyperphenylalaninemia (HPA) with a mutant phenylalanine hydroxylase (PAH) (EC 1.14.16.1) gene were recruited at 12 medical centers in Japan between June 1995 and July 2001. Therapeutic efficacy of BH(4) was evaluated in single-dose, four-dose, and 1-wk BH(4) loading tests followed by long-term BH(4) treatment, and also examined in relation to the PAH gene mutations. The endpoints were determined as the percentage decline in serum phenylalanine from initial values after single-dose (>20%), four-dose (>30%), and 1-wk BH(4) (>50%) loading tests. Patients with mild PKU exhibiting decreases in blood phenylalanine concentrations of >20% in the single-dose test also demonstrated decreases of >30% in the four-dose test. The 1-wk test elicited BH(4) responsiveness even in patients with poor responses in the shorter tests. Patients with mild HPA, many of whom carry the R241C allele, responded to BH(4) administration. No clear correlation was noted between the degree of decrease in serum phenylalanine concentrations in the single- or four-dose tests and specific PAH mutations. The 1-wk test (20 mg/kg of BH(4) per day) is the most sensitive test for the diagnosis of BH(4)-responsive PAH deficiency. Responsiveness apparently depends on mutations in the PAH gene causing mild PKU, such as R241C. BH(4) proved to be an effective therapy that may be able to replace or liberalize the phenylalanine-restricted diets for a considerable number of patients with mild PKU.     

Phenylketonuria masked by low protein feeds.

Two patients with phenylketonuria (PKU) requiring treatment were fed on low protein milks. Both had blood phenylalanine levels below 1200 micronmol/l (20mg/100 ml) until given a phenylalanine challenge. Phenylalanine content of mature breast milk may provide intakes similar to those used in treating PKU. Diagnosis of PKU is unlikely to be missed if screening is carried out on the sixth or seventh day of life because of higher phenylalanine in breast milk during the first week. Interpretation of screening tests requires knowledge of the infants'' feeds and a blood phenylalanine above 360 micronmol/l (6 mg/100 ml) in the absence of tyrosinaemia requires careful investigation.     

四氢生物蝶呤负荷试验诊断四氢生物蝶呤反应性苯丙氨酸羟化酶缺乏症的临床研究

目的探讨四氢生物蝶呤(BH4)反应性苯丙氨酸羟化酶(PAH)缺乏症的临床诊断方法,进一步了解其临床特征,为该型患儿应用BH4药物治疗提供科学依据。方法73例高苯丙氨酸血症(HPA)患儿,男47例,女26例,平均年龄1.93个月。所有患儿都进行口服BH4负荷试验,同时进行尿蝶呤谱分析、红细胞二氢蝶啶还原酶测定。对其中血苯丙氨酸(Phe)浓度<600μmol/L者给予口服Phe BH4联合负荷试验,对部分BH4反应性PAH缺乏症患儿,在普食条件下给予BH4片剂(10～20mg/kg)替代治疗6～7天,观察其疗效。结果(1)在BH4负荷试验中,不同类型HPA患儿的血Phe浓度表现出特征性的曲线改变,22例诊断为经典型苯丙酮尿症(PKU),39例中度PKU,12例四氢生物蝶呤缺乏症;(2)在中度PKU患儿中发现22例(56.4%)对BH4有反应;(3)6例BH4反应性PAH缺乏症患儿以BH410mg/kg治疗6～7天,其中4例血Phe浓度能控制到正常或接近正常治疗水平,另2例BH4需增加到20mg/kg使Phe浓度显著下降。结论在BH4负荷试验中,部分因苯丙氨酸羟化酶缺乏引起的中轻度PKU患儿对BH4有反应性,给予这些患儿BH4治疗可部分或全部替代低苯丙氨酸饮食治疗,拓宽了PKU的治疗方法,有助于提高患儿的生活质量。     

THE SEX RATIO IN PHENYLKETONURIA AND PERSISTENT HYPERPHENYLALANINAEMIA

The sex ratio in 76 children with an elevated serum phenylalanine level was studied in relation to their mode of ascertainment. The ratio of the sexes in the whole group was equal, but males outnumbered females 9:4 in classical cases of PKU discovered by means of the Guthrie test. This suggests that a proportion of females with classical PKU is being missed by the Guthrie test when this is performed in the first week of life. Males very markedly outnumber females in the group designated as having persistent hyperphenylalaninaemia. The value of a second follow-up screening test is emphasised.     

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目的探讨四氢生物蝶呤反应性苯丙氨酸羟化酶(PAH)缺乏症这一新的临床变异型在高苯丙氨酸血症(HPA)中的发生率,并进一步了解其PAH基因突变类型。方法2001年1月至2004年12月,上海第二医科大学附属新华医院收治的106例中位年龄2个月(0.5～59个月)的HPA患儿纳入研究。所有患儿做辅酶的羟生物蝶呤(BH4,20mg/kg)或联合血苯丙氨酸(Phe,100mg/kg)负荷试验、尿蝶呤谱分析及红细胞二氢蝶啶还原酶活性(DHPR)测定。以口服BH4后24h内血Phe浓度下降30%以上且排除BH4缺乏症为诊断标准。对13例BH4反应性PAH缺乏症患儿进行PAH基因突变检测。结果106例HPA者中41例(38.7%)为BH4反应性的PAH缺乏症。血Phe浓度在服用BH4前为(816±431)μmol/L,服BH4后24h内降至(267±198)μmol/L,反应下降率(67±19)%。41例尿蝶呤及DHPR活性均正常。106例中轻度HPA(18例)其BH4反应性PAH缺乏症发生率为61.1%(11/18)。13例做PAH基因突变检测,R241C为最多见突变类型(43.8%)。结论61.1%轻度HPA(11/18)及42.4%(28/66)轻度PKU对BH4有较大反应性。BH4负荷试验是该病有效而简便的鉴别诊断方法。     

Experience based on 800,000 newborn screening tests of the Budapest Phenylketonuria Centre

800 000 newborns were screened for hyperphenylalaninaemia by the Guthrie-test in the Budapest PKU Centre in the 10 and a half years since 1 May, 1973. The blood samples were taken from mature newborns on the fifth and from premature babies on the fourteenth day of life. All infants exhibiting a level equal to or exceeding 12 mg/dl were telegraphically invited to the Centre and those having a level of 15 mg/dl or higher were put on an appropriate diet. The patients were classified according to the result of the phenylalanine tolerance 73 were found to have classical phenylketonuria and 15 had atypical phenylketonuria. The total incidence of phenylketonuria was thus 1: 9091. The mean age at introduction of diet was 30 +/- 15 days during the first period, while 21 +/- 11 days during the second period. Infants having an initial value of 4-12 mg/dl were kept under continuous control; among them 69 were found to have benign hyperphenylalaninaemia (HPA). The PKU/HPA ratio amounted to 1.28. Both screening and care were carried out by the Centre, and the practice of care is described in detail. A preliminary evaluation of the therapeutical results with a view of the patients' social class is offered. Phenylalanine levels during the diet were greatly influenced by the familial background and the sociocultural environment.     

Tetrahydrobiopterin therapy of atypical phenylketonuria due to defective dihydrobiopterin biosynthesis.

A patient with atypical phenylketonuria (defective BH2 synthesis), detected at age 6 months because of severe muscle hypotonia and serum phenylalanine of 20 mg/100 ml, had normal activities of phenylalanine-4-hydroxylase and DHPR in liver biopsy, but only 2% activity in the phenylalanine-4-hyroxylase in vivo test using deuterated phenylalanine. After IV administration of 2.5 mg/kg chemically pure tetrahydrobiopterin bishydrochloride (BH4 . 2HCl), serum phenylalanine decreased from 20.4 to 2.1 mg/100 ml within 3 hours. Administration of 25 mg BH4 . HCl and 100 mg ascorbic acid through a gastric tube decrease; serum phenylalanine from 13.7 to less than 1.6 mg/100 ml within 3 hours and it remained less than 2 mg/100 ml for 2 days.     

Relation between genotype and phenotype in Swedish phenylketonuria and hyperphenylalaninemia patients

Phenylketonuria (PKU) and hyperphenylalaninemia (HPA) are caused mostly by an inherited (autosomal recessive) deficiency in hepatic phenylalanine hydroxylase (PAH) activity. More than 50 PAH mutations have ben reported. The goal of the present study was to examine the molecular basis for the clinical heterogeneity of Swedish PKU and HPA patients. Mutations were identified through allele-specific oligonucleotide hybridization or DNA sequencing on 128 of the 176 mutant alleles (73%). Three mutations (R408W, Y414C and IVS12) together accounted for 56% of all mutant alleles and ten relatively infrequent mutations were found on another 17% of all mutant alleles. Patients from 50 of the 88 families (57%) had identified mutations in both PAH genes and allowed use to compare the clinical effects of different combinations of PAH mutations. The in vitro activity of all of these mutations, including the newly identified G272X and L364, have been tested in a eukaryotic expression system. There was a strong relationship between the average in vitro PAH activity of the two mutant enzymes and both the phenylalanine tolerance and the neonatal pretreatment serum phenylalanine concentration. This confirms previous observations in Danish and German PKU patients that disease phenotype is a consequence of the nature of the mutations at the PAH locus and not significantly influenced by other loci. The sample population in the previous study did not, however, include mild HPA patients, and the observed correlation is thus restricted to severe and moderate mutant alleles. Since a comparatively high proportion of the Swedish patients were mildly affected, we have provided additional evidence that this correlation is valid throughout a continuous spectrum of clinical varieties. PAH genotyping could therefore help predict prognosis of a recently diagnosed PKU or HPA child.     

Changing incidence of neonatal hypermethioninaemia: implications for the detection of homocystinuria.

The Guthrie test was used to measure blood methionine concentrations in 670 764 neonates during the period from May 1970 to December 1977. Raised values (greater than 4 mg/100 ml; 268 mumol/l) were found in 147 babies (6--14 days old) and 55 of these still had raised values when retested 2--6 weeks later. 48 infants had transient hypermethioninaemia of at least 3 weeks'' duration, one had a more persistent form associated with abnormal liver function tests, 3 had different forms of homocystinuria, and one infant, who was asymptomatic at the time of detection, had hypermethioninaemia associated with a rapidly fatal form of tyrosinamiea (tyrosinosis). Two infants could not be followed up. Transient hypermethioninaemia has not been detected in this laboratory since 1975. There was a greatly reduced incidence of transient hypermethioninaemia in girls after 1972 and in boys after 1975; this may have been due to recent changes in infant practices in the UK. Homocystinuria was last detected in this laboratory in 1972; the apparent change in incidence is significant (P less than 0.05) and suggests that the diagnostic value of this screening procedure should be reassessed.     

Genetic background of hyperphenylalaninemia in Nagasaki,Japan

Phenylketonuria (PKU) and related hyperphenylalaninemia (HPA) are caused by a deficiency in hepatic phenylalanine hydroxylase (PAH). The incidence of PKU in Nagasaki prefecture is higher than that in all parts of Japan (1/15 894 vs 1/120 000). To investigate the genetic background of patients with HPA in Nagasaki prefecture, mutation analysis was done in 14 patients with PKU or mild HPA. Homozygous or compound heterozygous PAH mutations were identified in all the patients. The spectrum of PAH mutations in the cohort was broad and similar to those in all parts of Japan and East Asian countries. R53H is the most common mutation in patients with mild HPA. The present results provide further support for genotype–phenotype correlations in patients with HPA. The high incidence of PKU in Nagasaki, the westernmost part of Japan, might be due to migration of people with PAH mutations from China and Korea, and geographic factors.     

Assessment of tetrahydrobiopterin responsiveness in Turkish hyperphenylalaninemic patients

Tetrahydrobiopterin (BH4) therapy is the latest alternative approach in phenylalanine hydroxylase (PAH) deficiency, and is suggested for a number of hyperphenylalaninemic (HPA) patients with certain mutations. In our unit, therapeutic efficacy of BH4 was evaluated in 20 HPA patients (4 mild HPA, 9 mild phenylketonuria-PKU, 7 moderate PKU) by a single oral dose of BH4. Overall, 60% of the patients responded (45% favorably, 15% partially). All of the mild HPA patients and 55% of mild PKU patients responded to BH4 favorably and an additional 11% of mild PKU patients responded partially. Of 7 moderate PKU patients, 2 responded partially (28%). The genotypes of the patients who responded to BH4 favorably were: DelF39/-, L48S/L48S, R261Q/- (4 patients), A300S/IVS2nt5g > c, A300S/-, E390G/E390G. The genotypes of the patients who exhibited a partial response were: L48S/L48S, R261Q/ R261Q, IVS10nt546/-. We concluded that since there are too many mutations and many patients are compound heterozygote, it is difficult to predict BH4 responsiveness based solely on genotype, especially for the mutations which show inconsistent phenotypes. The best way to identify the patients who are more likely to benefit from BH4 administration is performing BH4 loading test. Long-term BH4 loading test should be performed in classical and moderate PKU patients to confirm that they are not responsive to BH4.     

Three-year audit of the hyperphenylalaninaemia/phenylketonuria spectrum in Victoria

AIMS: To determine the prevalence, the types and severity of hyperphenylalaninaemia (including phenylketonuria (PKU)) in Victoria and to report on a new treatment modality of PKU. METHODS: We reviewed the medical records of all patients diagnosed with high blood phenylalanine levels by newborn screening between November 2001 and October 2004. RESULTS: We identified 17 newborn babies with high levels of blood phenylalanine (total samples: 190,835). Dihydrobiopterin reductase deficiency was excluded in all babies. Five babies had persistent phenylalanine levels of 200-300, and do not receive any dietary or pharmaceutical therapy. One baby was diagnosed as having pyruvoyl tetrahydro-pterin synthase deficiency. Following reports of tetrahydrobiopterin (BH(4))-responsive PKU, we have performed a BH(4) load (20 mg/kg, 6R-5,6,7,8-tetrahydro-L-biopetrin dehydrochloride; Schricks Laboratories, Jona, Switzerland) in 10 newborn babies with PKU (one baby with a phenylalanine level of 2600 micromol/L was started on diet without prior load). Three babies had a significant response to BH(4) (>35% decrease in phenylalanine level). Protein restriction (1.2 g/kg/day) and introduction of phenylalanine-free formula, in addition to BH(4) treatment, were necessary in one patient. The other patients maintain good metabolic control with BH(4) treatment only (at approximately 11 mg/kg/day) and an intake of 2-3 g protein per day. Of the nine babies who are on a full PKU diet, three have high phenylalanine tolerance (consistently >40 mg/kg/day). CONCLUSION: There is a spectrum of severity of hyperphenylalaninaemia in the population. The detection of BH(4)-responsive PKU patients offers them a less restrictive dietary regimen and an improved quality of life, and may enable near normal life-style in adolescence.     

Intellectual and Developmental Status in Children With Hyperphenylalaninemia and PKU Who Were Screened in a National Program

Background:

Hyperphenylalaninemia (HPA) and Phenylkeonuria (PKU) are metabolic errors caused by deficiency of phenylalanine hydroxylase enzyme, which results in increased level of phenylalanine. This increase is toxic to the growing brain.

Objectives:

The purpose of this study was to compare the intellectual and developmental status in HPA and PKU children with normal population in national screening program.

Patients and Methods:

In a historical cohort study, 41 PKU patients who had the inclusion criteria and 41 healthy children were evaluated. Wechsler preschool and primary scale of intelligence-3rd edition (WPPI-3) was used in order to assess the intellectual status of children 4 years and older and Ages and stages questionnaire (ASQ) was used to assess the developmental status of children 5 years and younger.

Results:

In intellectual test comparison, the two groups showed significant difference in Wechsler’s performance intelligence score and some performance subscales (P-value < 0.01). In comparison of developmental status, no significant difference was observed between the two groups (P-value > 0.05).

Conclusions:

Even with early diagnosis and treatment of PKU patients, these children show some deficiencies intellectually compared to normal children. This study emphasizes on necessity for screening intellectual and developmental status of PKU patients so that effective medical or educational measures can taken in case of deficiencies.