Phenylalanine and Tyrosine Metabolism Analysis in Heterozygotes for Phenylketonuria and in Healthy Individuals

Andrade, Roseani; Monteiro, Vaneisse; Cruz, Cleber; Silva, Carla; Bastos, Adriana; Silva, Luiz

doi:10.1177/2326409815573962

Abstract

Phenylketonuria (PKU) is an inherited metabolic disorder derived from a deficiency in the enzyme phenylalanine hydroxylase, which converts the amino acid phenylalanine (Phe) into tyrosine (Tyr). Here we aimed to examine the metabolism of Phe and Tyr in heterozygotes for PKU during fasting and after oral overload of Phe (25 mg/kg). Plasma concentration of Phe and Tyr and Phe²–Tyr ratio were determined under fasting condition or 30, 45, 60, and 90 minutes after Phe overload. The sample consisted of 50 participants: 23 heterozygotes for PKU (10 men and 13 women) and a control group of 27 healthy individuals (13 men and 14 women). The dosage of Phe at 45 and 90 minutes and the micromolar fraction of Phe²/Tyr after 90 minutes of overload efficiently differentiated PKU heterozygotes. The discriminant function revealed 86% of accuracy. In fact, 94.4% of heterozygotes for PKU were correctly classified.

Keywords
inborn errors of metabolism; heterozygotes; phenylalanine; overload

Introduction

Phenylketonuria (PKU) is an autosomal recessive disorder due to partial or total deficiency of the phenylalanine-4-hydroxylase (PAH), leading to an impaired conversion of amino acid phenylalanine (Phe) into amino acid tyrosine (Tyr).¹1 Donlon, J, Levy, HL, Scriver, CR. Hyperphenylalanine: phenylalanine hydroxylase deficiency. In: Scriver, CR ed., The Metabolic and Molecular Bases of Inherited Diseases. New York: McGraw-Hill; 2010.

The PAH gene maps the 12q23.2 region of the chromosome 12 chromosome and contains 13 exons.²2 Woo, ICS, lidsky, AS, Guttler, F. Cloned human phenylalanine hydroxylase gene allows prenatal diagnosis and carrier detection of classical phenylketonuria. Nature. 1983;306 (5939):151–155. The PKU is not only characterized by phenotypic heterogeneity, but it also presents molecular heterogeneity. In fact, approximately 600 mutations have been described for the PAH gene.³3 http://www.pahdb.mcgill.ca. Accessed 7 June 2014. Updated 31 August 2009. Published August 2009. Phenylalanine-4-hydroxylase is mainly localized in the liver, hampering its direct evaluation. In this scenario, biochemical assays for PKU evaluation are indirect and are carried through the measurement of plasma Phe and Tyr.⁴4 Silva, LCS, Carvalho, TS, Silva, FB, Pires, RF, Giugliani, R, Pereira, ML. Aspartame loading test in PKU heterozygous individuals bearing severe and moderate mutations. Clin Genet. 2000;58 (1):86–88.

The accurate classification for heterozygotes is valuable for linkage analysis studies and may assist in estimating the genic frequency as well as in genetic counseling. Studies have demonstrated that a precise discrimination of individuals with tetrahydrobiopterin hyperphenylalaninemia can be achieved by enzymatic assays.⁵5 Scriver, CR . The salience of Garrod's ‘molecular groupings’ and ‘Inborn Factors in Disease’. J Inherit Metab Dis. 1989;12 (1):9–24.

6 Blau, N, Curtius, HCh, Endres, W. Effect of high-protein meal plus aspartame ingestion on plasma phenylalanine concentrations in obligate heterozygotes for phenylketonuria. Metabolism. 1994;43 (4):413–416.-⁷7 Scriver, CR, Clow, CL, Kaplan, P, Niederwieser, A. Hyperphenylalaninemia due to deficiency of 6-pyruvoyl tetrahydropterin synthase. Unusual gene dosage effect in heterozygotes. Hum Genet. 1987;77 (2):168–171. However, diagnosis of PAH-deficient patients is still a challenge.

Because PAH is particularly activated in liver, enzymatic activity detection do not have practical relevance for heterozygotes screening. However, few investigation using liver tissue have revealed that the activity of this enzyme in heterozygotes is about 30% compared with PHA activity in patients with PKU, which is less than 1%.⁸8 Lehmann, WD . Progress in the identification of the heterozygote in phenylketonuria. J Pedriatr. 1989;114 (6):915–924.

In the late 1950s, Hsia and colleagues⁹9 Hsia, DYY, Driscoll, KU, Troll, W. Detection by phenylalanine tolerance test of heterozygous carrier of phenylketonuria. Nature. 1956;178 (4544):1239–1240. have demonstrated that oral Phe overload may allow the detection of heterozygotes in the population using the differences in Phe concentration. Indeed, serum levels of Phe were 2-fold higher in heterozygotes after Phe overload (100 mg/kg). These findings were also in line with reduced PAH activity in heterozygotes.⁹9 Hsia, DYY, Driscoll, KU, Troll, W. Detection by phenylalanine tolerance test of heterozygous carrier of phenylketonuria. Nature. 1956;178 (4544):1239–1240.

These investigations primarily initiated other biochemical studies used for PKU detection in heterozygotes. The majority of the employed methods to distinguish PKU heterozygotes from healthy individuals are based on evaluation of blood levels of Phe and Tyr after an oral,⁹9 Hsia, DYY, Driscoll, KU, Troll, W. Detection by phenylalanine tolerance test of heterozygous carrier of phenylketonuria. Nature. 1956;178 (4544):1239–1240.

10 Rampini, S, Anders, PW, Curtius, HC, Marthaler, T. Detection of heterozygotes for phenylketonuria by column chromatography and discriminatory analysis. Pediatr Rev. 1969;3 (4):287–297.-¹¹11 Gutter, F., Hansen, G. Heterozygote detection in phenylketonuria. Clin Genet. 1977;11 (2):137–146. intravenous¹²12 Jagenburg, R., Rodger, S. Detection of heterozygotes for phenylketonuria by constant intravenous infusion of L-phenylalanine. Clin Chem. 1977;23 (9):1661–1665. Phe overload or deuterium-labeled administration.¹³13 Lehmann, WD, Theobald, N, Heinrich, HC, Clemens, P, Grüttner, R. Detection of heterozygous carriers for phenylketonuria by a L-[2H5] phenylalanine stable isotope loading test. Clinica Chimica Acta. 1984;138 (1):59–71. In this concern notwithstanding the analyses of a single parameter (Phe) may not correctly distinguish both the groups.¹⁴14 Sartorio, R, Greco, L, Carrozzo, R, Budillon, C, Andria, G. Simplified test to detect PKU heterozygotes by discriminant analysis in mentally retarded children and their mothers. Clin Genet. 1988;33 (4):241–245. Therefore, multivariate combinations of different parameters such as levels of Phe and Tyr and the micromolar Phe–Tyr and Phe²–Tyr ratios have been proposed as discriminant functions with reduced classification error. Additionally, the graphs of micromolar ratios are also recommended for obtaining a higher accuracy in detection of heterozygotes.¹⁰10 Rampini, S, Anders, PW, Curtius, HC, Marthaler, T. Detection of heterozygotes for phenylketonuria by column chromatography and discriminatory analysis. Pediatr Rev. 1969;3 (4):287–297.,¹¹11 Gutter, F., Hansen, G. Heterozygote detection in phenylketonuria. Clin Genet. 1977;11 (2):137–146.,¹⁴14 Sartorio, R, Greco, L, Carrozzo, R, Budillon, C, Andria, G. Simplified test to detect PKU heterozygotes by discriminant analysis in mentally retarded children and their mothers. Clin Genet. 1988;33 (4):241–245.

15 Griffin, RF, Elsas, LJ. Classic phenylketonuria: diagnosis through heterozygote detection. J Pediatr. 1975;86 (4):512–517.

16 Tenenholz, B, Wenger, SL, Breck, J, Steele, MW. A simplified PKU gene carrier detection test using fasting blood. Clin Genet. 1983;23 (2):115–119.

17 Freehauf, CL, Lezotte, D, Goodman, SI, McCabe, ER. Carrier screening for phenylketonuria; comparison of two discriminant analysis procedures. Am J Hum Genet. 1984;36 (6):1180–1189.-¹⁸18 Guneral, F, Ozalp, I, Tatlidil, H. Heterozygous carriers of classical phenylketonuria in a sample of the Turkish population: detection by a spectrofluorimetric method. J Inher Metab Dis. 1991;14 (5):741–748. The use of such methods is simple and low cost and can be justified by the high frequency of heterozygotes in the population (1:50-1:70), as well as by its preventive potential, since it may allow genetic counseling and prenatal diagnosis.¹⁹19 Silva, LCS, Pires, RF, Coelho, JC, Jardim, LB, Giugliani, R. Evaluation of an aspartame-loading test for the detection of heterozygotes for classical phenylketonuria. Clin Genet. 1997;51 (4):231–234.

Aim

The present study was tailored to analyze which parameters (Phe, Tyr, Phe/Tyr, and Phe²/Tyr) possessed the power of distinguishing PKU heterozygotes from healthy individuals. This approach can be used to track PKU heterozygotes in high-risk families.

Methods

The sample enrolled 23 obliged heterozygotes from 18 to 45 years of age (10 men and 13 women). The control group was composed by 27 individuals (13 men and 14 women) from 18 to 44 years of age. All participants were in fasting condition for at least 10 hours. Five blood samples were collected. The basal sample was collected during fasting (T0). Afterward, amino acid Phe (25 mg/kg weight) diluted in water was orally administered, and 4 more samples were subsequently collected 30, 45, 60, and 90 minutes after the overload (T30, T45, T60, and T90, respectively).

After the sample collection, plasma was separated and frozen at −20°C until the quantitative analyses of the amino acids Phe and Tyr. Women who were pregnant or taking contraceptive pills were not included in the study. Dosage of Tyr and Phe was duplicated in accordance with the fluorometric methods of McCaman and Robins²⁰20 McCaman, M., Robins, E. Fluometric method for the determination of phenylalanine in serum. J Lab Clin Med. 1962;59(5):885–890. and Philips,²¹21 Philips, RE . Tyrosine in serum. In: Turner, GK , ed., Manual of Fluorimetric Clinical Procedures. Palo Alto: GK Turner Associates; 1967. respectively.

In accordance with Brazilian Resolution #196/96, the present study was approved by the Ethic Committee of the Institute of Health Sciences of the Federal University of Pará under the protocol #088/08.

Statistics

Both groups were statically compared using 4 parameters, namely, plasma levels of Phe and Tyr and the results of the Phe–Tyr and Phe²–Tyr ratios. Longitudinal interferences (within-subject) were applied by means of tests for paired samples, such as Student . and Wilcoxon tests. Transversal comparisons (between-subject) were made using Student . test and Mann-Whitney . test. The evaluation of the operational performance of the amino acids was made using receiver–operating characteristic (ROC) curve. The variables with better performance, in accordance with ROC curve, were submitted to discriminant analysis model to validate the efficiency of the model. The level of significance was set at P < .05.

Results

The longitudinal analysis of Phe, Tyr, Phe/Tyr, and Phe²/Tyr (Figure 1) revealed that the maximum peak of level was at 30 and 45 minutes after Phe overload for control and heterozygote groups, respectively. After overload, all of the obtained values were higher than baseline in both the groups (P < .05). In the control group, the highest peak of Tyr happened 30 minutes after overload, and all subsequent values were statically different from fasting condition (P < .05, baseline). In the heterozygote group, Tyr reached the highest peak 60 minutes after overload and only T45 and T60 reached statistical difference compared to T0 (P < .05, Figure 1B). Considering the between-group analysis, Phe was significantly higher in the heterozygote group in T0, T45, T60, and T90. In control group, higher values of Tyr were found in T30, T45, and T90. The Phe–Tyr and Phe²–Tyr ratios displayed higher values in heterozygote group in all tested intervals (P < .05).

Figure 1
Mean and standard error of the Phe (a), Tyr (b), Phe/Tyr (c), and Phe²/Tyr (d) parameters in the control group (n = 27) or the heterozygote group (n = 23) in the basal condition or 30, 45, 60, and 90 minutes after the Phe oral overload (T0, T30, T45, T60, and T90, respectively). Phe indicates phenylalanine; Tyr, tyrosine.

Table 1 details the indicators of sensitivity, specificity, and cutoff for the Phe, Tyr, Phe/Tyr, and Phe²/Tyr parameters. These indicators were used in the ROC curve construction (Figure 2).

Figure 2
ROC curve of the Phe (a), Tyr (b), Phe/Tyr (c), Phe/Tyr, and Phe²/Tyr (d) parameters. Phe indicates phenylalanine; Tyr, tyrosine.

Thumbnail

Table 1
Sensitivity, Specificity, and Cutoff for the Variables Phe, Tyr, Phe/Tyr, and Phe²/Tyr.

Figure 3 depicts the ROC curve used in comparison of the 3 best-obtained results (Phe T45, Phe T90, and Phe²/Tyr T90). These parameters were chosen because they ablest expressed the differences between heterozygotes and the control groups, thus being selected to the multivariate model (discriminant analysis).

Figure 3
ROC curve of the best parameters (Phe after 45 minutes of the oral Phe overload and Phe and Phe²/TyrT90 after 90 minutes of oral overload). Phe indicates phenylalanine; Tyr, tyrosine; ROC, receiver operating characteristic.

Using the discriminant functions Y′ = −0.0996 X1 + 0.9928 X2 + 0.0668 X3 and Y˝= 0.1000 X1 + 0.9801 X2 − 0.1717 X3, a diagram was plotted to support the classification of each patient from the heterozygote and control groups in accordance with the predictive variables in which X1, X2, and X3 were Phe T45, Phe T90, and Phe²/Tyr, respectively. Table 2 shows the final classification of both the groups in line with the discriminant functions.

Thumbnail

Table 2
Classification of Participants From Both Groups Tested for Discriminant Equation.

Figure 4 displays 6 individuals from the heterozygote group that, after the Phe overload, whose values were lower than expected for PKU homozygotes (false negative) and 3 individuals from the control groups who presented values similar to heterozygotes (false positive).

Figure 4
Classification heterozygote and control group participants.

Discussion

The absence of satisfactory techniques to detect the enzyme PAH in PKU heterozygotes allied to the difficult molecular analysis of PAH gene due to vast number of mutations has contributed to the implementation of biochemical reliable tests to distinguish between PKU heterozygotes from healthy individuals.

The parameters here employed were chosen taking into account that the expected hydroxylation rate of Phe for Tyr is smaller in heterozygotes than in healthy individuals. Thus, healthy individuals should present higher plasma levels of Tyr. Considering that heterozygotes may display increased levels of Phe and reduced levels of Tyr, one may propose Phe–Tyr and Phe²–Tyr ratios usage to augment the distinction between PKU heterozygotes and healthy individuals, although some studies had already described important overlapping zones when these parameters are applied.⁴4 Silva, LCS, Carvalho, TS, Silva, FB, Pires, RF, Giugliani, R, Pereira, ML. Aspartame loading test in PKU heterozygous individuals bearing severe and moderate mutations. Clin Genet. 2000;58 (1):86–88.,²¹21 Philips, RE . Tyrosine in serum. In: Turner, GK , ed., Manual of Fluorimetric Clinical Procedures. Palo Alto: GK Turner Associates; 1967.

In the control group, all of the obtained values of Phe after overload were significantly higher than T0. These findings are in agreement with previous studies.²³23 Alós, T, Bel, Y, Cabello, ML. Improved identification of heterozygotes for phenylketonuria using blood neopterin. J Inher Metab Dis. 1993;16 (2):457–462. The levels of Phe progressively increased and reached the highest peak at 30 minutes after overload administration, suggesting that Phe is being rapidly metabolized into Tyr. Statistical differences for Tyr levels were detected after T30, corroborating the metabolization of Phe into Tyr. What concerns Phe/Tyr and Phe²/Tyr ratios, the highest peak occurred in T30. These findings are in line with previous studies.¹⁸18 Guneral, F, Ozalp, I, Tatlidil, H. Heterozygous carriers of classical phenylketonuria in a sample of the Turkish population: detection by a spectrofluorimetric method. J Inher Metab Dis. 1991;14 (5):741–748.,²⁴24 Hilton, MA, Sharpe, JN, Hicks, LG, Andrews, BF. A simple method for detection of heterozygous carriers of the gene for classic phenylketonuria. J Pediatr. 1986;109 (4):601–604.

In the heterozygote group, the mean value of Phe, Phe/Tyr, and Phe²/Tyr reached the peak at T45, suggesting that the metabolization of Phe into Tyr was slower for this group compared to the control group. In accordance, Tyr levels were higher at T60. These results were also found by Silva and colleagues.⁴4 Silva, LCS, Carvalho, TS, Silva, FB, Pires, RF, Giugliani, R, Pereira, ML. Aspartame loading test in PKU heterozygous individuals bearing severe and moderate mutations. Clin Genet. 2000;58 (1):86–88.

When both groups were compared during fasting condition and after Phe overload, Phe serum concentration was increased in the heterozygote group, corroborating previous findings.⁴4 Silva, LCS, Carvalho, TS, Silva, FB, Pires, RF, Giugliani, R, Pereira, ML. Aspartame loading test in PKU heterozygous individuals bearing severe and moderate mutations. Clin Genet. 2000;58 (1):86–88.,²⁵25 Verduci, E, Riva, E, Agostini, C. Phenylalanine hydroxilase mutations and phenylalanine-tyrosine metabolism in heterozygotes for phenylalanine hydroxylase deficiency. Acta Pediatr. 2002;91 (7):805–810. The largest difference between the 2 groups occurred at T60. Garcia and coworkers²⁶26 Garcia, EG, Garcia, BB, González, JM. Estudio de portadores de fenilcetonuria y otras hiperfenilalaninemias por prueba de tolerancia a la fenilalanina. Rev Cubana Pediatr. 1993;65 (2):88–92. have verified that the levels of Tyr in the heterozygote group were 2-fold increased compared to control and that the major difference also occurred 60 minutes after the overload.

Still concerning Tyr parameter, the levels of this amino acid were decreased in the heterozygotes at T30, T45, and T90. In line with data found by Guldberg et al²²22 Guldberg, P, Henriksen, KF, Lou, HC, Güttler, F. Aberrant phenylalanine metabolism in phenylketonuria heterozygotes. J Inher Metab Dis. 1998;21 (4):365–372. and Spada et al,²⁷27 Spada, M, Dianzani, I, Bonetti, G. Phenylalanine and tyrosine metabolism in phenylketonuria heterozygotes: Influence of different phenylalanine hydroxylase mutations. J Inher Metab Dis. 1998;21 (3):236–239. the greatest difference between experimental and control groups occurred at T30.

The variables Phe/Tyr and Phe²/Tyr were increased in the heterozygotes throughout the measured period. This finding is in agreement with those from Silva et al,¹⁹19 Silva, LCS, Pires, RF, Coelho, JC, Jardim, LB, Giugliani, R. Evaluation of an aspartame-loading test for the detection of heterozygotes for classical phenylketonuria. Clin Genet. 1997;51 (4):231–234. Song et al,²⁸28 Song, L, Xu, F, Meng, Y. A study of phenylketonuria heterozygotes screening. Chin J Med Genet. 2001;8 (1):56–58. and Abdalla et al.²⁹29 Abdala, EM . Detection of heterozygous carriers of pku in egypt: successful application of a simple biochemical method. J Egypt Public Health Assoc. 2008;83 (3-4):239–254.

The analysis of the ROC curve revealed that the best parameters to differentiate PKU heterozygotes from healthy individuals were, in the order, Phe after 45 and 90 minutes of overload and Phe²/Tyr after 90 minutes. Of note, Phe²/Tyr at T90 had presented the best performance in the previous study from Abdalla et al.²⁹29 Abdala, EM . Detection of heterozygous carriers of pku in egypt: successful application of a simple biochemical method. J Egypt Public Health Assoc. 2008;83 (3-4):239–254.

We intended to increase the differentiation degree between both groups. Therefore, discriminant functions were elaborated using the 3 best parameters obtained here. Thus, we found sensitivity of 73.91% and specificity of 88.89%. The rates of false positive and false negative were 11.11% and 26.09%, respectively. The positive predictive value of the test was 94.4%, and the negative predictive value was 81.25%. In the study of Silva and colleageues,¹⁹19 Silva, LCS, Pires, RF, Coelho, JC, Jardim, LB, Giugliani, R. Evaluation of an aspartame-loading test for the detection of heterozygotes for classical phenylketonuria. Clin Genet. 1997;51 (4):231–234. the discriminant function that considered fasting condition was found to be more efficient than the one that considered the variables after aspartame overload. In that work, the discriminant function correctly classified 98% of individuals with 97% of accuracy.

Here, when the discriminant function was applied, 6 false-negative cases were detected in the heterozygote group (26.09%, 4 male and 2 female). In the control group, 3 false-positive cases were detected (11.11%, 2 male and 1 female). In the work from Silva et al,¹⁹19 Silva, LCS, Pires, RF, Coelho, JC, Jardim, LB, Giugliani, R. Evaluation of an aspartame-loading test for the detection of heterozygotes for classical phenylketonuria. Clin Genet. 1997;51 (4):231–234. which used aspartame overload instead (100 mg/kg, containing 56 mg/kg of Phe), 3 participants (all women) from the control group presented with Phe values above the expected for healthy individuals and 1 PKU heterozygote displayed lower probable values for this condition. It should be highlighted that the exclusion criteria were previously determined in the present study. Specifically, use of contraceptives pills, menstrual period, and pregnancy were among them because they can potentially interfere with Phe metabolism and mislead to classification of an individual as PKU heterozygote. Among this cited factors, contraceptive pills have the greatest probability of inducing such an error. Additionally, iron deficiency anemia should also be considered. A small possibility of having heterozygotes in the control group can be discarded since the frequency in the population is 1:50 to 1:70.⁴4 Silva, LCS, Carvalho, TS, Silva, FB, Pires, RF, Giugliani, R, Pereira, ML. Aspartame loading test in PKU heterozygous individuals bearing severe and moderate mutations. Clin Genet. 2000;58 (1):86–88.,⁸8 Lehmann, WD . Progress in the identification of the heterozygote in phenylketonuria. J Pedriatr. 1989;114 (6):915–924.,³⁰30 Blitzer, MG, Bailey-Wilson, JE, Shapira, E. Discrimination of heterozigotes for phenylketonuria, persistent hyperphenylalaninemia and controls by phenylalanine loading. Clin Chim Acta. 1986;161 (3):347–352.

Conclusion

The present study is original regarding the dosage of Phe after overload (25 mg/kg) and the distinct time points employed to evaluate the metabolism of amino acid Phe and Tyr. The ROC curve had demonstrated that the Phe at T45 and T90 and Phe²/Tyr at T90 were the best parameters to differentiate PKU heterozygotes from healthy individuals. Considering our results, a large range of differentiation was obtained after 45 minutes of Phe overload. The discriminant analysis revealed an accuracy rate of 86%. In addition, 94.4% of the PKU heterozygotes were correctly classified.

Funding

This study was supported by MCT/CNPq/CT (grant: 402050/2010-0) and Brazilian Institute for Population Medical Genetics (INAGEMP – grant: CNPq 573993/2008-4) funding.

References

¹
Donlon, J, Levy, HL, Scriver, CR. Hyperphenylalanine: phenylalanine hydroxylase deficiency. In: Scriver, CR ed., The Metabolic and Molecular Bases of Inherited Diseases. New York: McGraw-Hill; 2010.
²
Woo, ICS, lidsky, AS, Guttler, F. Cloned human phenylalanine hydroxylase gene allows prenatal diagnosis and carrier detection of classical phenylketonuria. Nature. 1983;306 (5939):151–155.
³
http://www.pahdb.mcgill.ca. Accessed 7 June 2014. Updated 31 August 2009. Published August 2009.
⁴
Silva, LCS, Carvalho, TS, Silva, FB, Pires, RF, Giugliani, R, Pereira, ML. Aspartame loading test in PKU heterozygous individuals bearing severe and moderate mutations. Clin Genet. 2000;58 (1):86–88.
⁵
Scriver, CR . The salience of Garrod's ‘molecular groupings’ and ‘Inborn Factors in Disease’. J Inherit Metab Dis. 1989;12 (1):9–24.
⁶
Blau, N, Curtius, HCh, Endres, W. Effect of high-protein meal plus aspartame ingestion on plasma phenylalanine concentrations in obligate heterozygotes for phenylketonuria. Metabolism. 1994;43 (4):413–416.
⁷
Scriver, CR, Clow, CL, Kaplan, P, Niederwieser, A. Hyperphenylalaninemia due to deficiency of 6-pyruvoyl tetrahydropterin synthase. Unusual gene dosage effect in heterozygotes. Hum Genet. 1987;77 (2):168–171.
⁸
Lehmann, WD . Progress in the identification of the heterozygote in phenylketonuria. J Pedriatr. 1989;114 (6):915–924.
⁹
Hsia, DYY, Driscoll, KU, Troll, W. Detection by phenylalanine tolerance test of heterozygous carrier of phenylketonuria. Nature. 1956;178 (4544):1239–1240.
¹⁰
Rampini, S, Anders, PW, Curtius, HC, Marthaler, T. Detection of heterozygotes for phenylketonuria by column chromatography and discriminatory analysis. Pediatr Rev. 1969;3 (4):287–297.
¹¹
Gutter, F., Hansen, G. Heterozygote detection in phenylketonuria. Clin Genet. 1977;11 (2):137–146.
¹²
Jagenburg, R., Rodger, S. Detection of heterozygotes for phenylketonuria by constant intravenous infusion of L-phenylalanine. Clin Chem. 1977;23 (9):1661–1665.
¹³
Lehmann, WD, Theobald, N, Heinrich, HC, Clemens, P, Grüttner, R. Detection of heterozygous carriers for phenylketonuria by a L-[2H5] phenylalanine stable isotope loading test. Clinica Chimica Acta. 1984;138 (1):59–71.
¹⁴
Sartorio, R, Greco, L, Carrozzo, R, Budillon, C, Andria, G. Simplified test to detect PKU heterozygotes by discriminant analysis in mentally retarded children and their mothers. Clin Genet. 1988;33 (4):241–245.
¹⁵
Griffin, RF, Elsas, LJ. Classic phenylketonuria: diagnosis through heterozygote detection. J Pediatr. 1975;86 (4):512–517.
¹⁶
Tenenholz, B, Wenger, SL, Breck, J, Steele, MW. A simplified PKU gene carrier detection test using fasting blood. Clin Genet. 1983;23 (2):115–119.
¹⁷
Freehauf, CL, Lezotte, D, Goodman, SI, McCabe, ER. Carrier screening for phenylketonuria; comparison of two discriminant analysis procedures. Am J Hum Genet. 1984;36 (6):1180–1189.
¹⁸
Guneral, F, Ozalp, I, Tatlidil, H. Heterozygous carriers of classical phenylketonuria in a sample of the Turkish population: detection by a spectrofluorimetric method. J Inher Metab Dis. 1991;14 (5):741–748.
¹⁹
Silva, LCS, Pires, RF, Coelho, JC, Jardim, LB, Giugliani, R. Evaluation of an aspartame-loading test for the detection of heterozygotes for classical phenylketonuria. Clin Genet. 1997;51 (4):231–234.
²⁰
McCaman, M., Robins, E. Fluometric method for the determination of phenylalanine in serum. J Lab Clin Med. 1962;59(5):885–890.
²¹
Philips, RE . Tyrosine in serum. In: Turner, GK , ed., Manual of Fluorimetric Clinical Procedures. Palo Alto: GK Turner Associates; 1967.
²²
Guldberg, P, Henriksen, KF, Lou, HC, Güttler, F. Aberrant phenylalanine metabolism in phenylketonuria heterozygotes. J Inher Metab Dis. 1998;21 (4):365–372.
²³
Alós, T, Bel, Y, Cabello, ML. Improved identification of heterozygotes for phenylketonuria using blood neopterin. J Inher Metab Dis. 1993;16 (2):457–462.
²⁴
Hilton, MA, Sharpe, JN, Hicks, LG, Andrews, BF. A simple method for detection of heterozygous carriers of the gene for classic phenylketonuria. J Pediatr. 1986;109 (4):601–604.
²⁵
Verduci, E, Riva, E, Agostini, C. Phenylalanine hydroxilase mutations and phenylalanine-tyrosine metabolism in heterozygotes for phenylalanine hydroxylase deficiency. Acta Pediatr. 2002;91 (7):805–810.
²⁶
Garcia, EG, Garcia, BB, González, JM. Estudio de portadores de fenilcetonuria y otras hiperfenilalaninemias por prueba de tolerancia a la fenilalanina. Rev Cubana Pediatr. 1993;65 (2):88–92.
²⁷
Spada, M, Dianzani, I, Bonetti, G. Phenylalanine and tyrosine metabolism in phenylketonuria heterozygotes: Influence of different phenylalanine hydroxylase mutations. J Inher Metab Dis. 1998;21 (3):236–239.
²⁸
Song, L, Xu, F, Meng, Y. A study of phenylketonuria heterozygotes screening. Chin J Med Genet. 2001;8 (1):56–58.
²⁹
Abdala, EM . Detection of heterozygous carriers of pku in egypt: successful application of a simple biochemical method. J Egypt Public Health Assoc. 2008;83 (3-4):239–254.
³⁰
Blitzer, MG, Bailey-Wilson, JE, Shapira, E. Discrimination of heterozigotes for phenylketonuria, persistent hyperphenylalaninemia and controls by phenylalanine loading. Clin Chim Acta. 1986;161 (3):347–352.

Publication Dates

Publication in this collection
19 June 2019
Date of issue
2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited.

[1] This study was supported by MCT/CNPq/CT (grant: 402050/2010-0) and Brazilian Institute for Population Medical Genetics (INAGEMP – grant: CNPq 573993/2008-4) funding.

		Sensitivity	Specificity	Distance	Cutoff
Phe	T45	0.869	0.926	0.150	3.960
	T60	0.782	0.926	0.230	3.240
	T90	0.869	0.852	0.197	2.710
Tyr	T30	0.815	0.783	0.286	1.290
	T45	0.778	0.689	0.377	1.220
	T90	0.825	0.652	0.378	1.150
Phe/Tyr	T0	0.738	0.778	0.343	1.340
	T30	0.739	0.815	0.320	2.650
	T45	0.826	0.815	0.254	2.480
	T60	0.957	0.630	0.373	1.910
	T90	0.913	0.778	0.239	2.030
Phe²/Tyr	T0	0.783	0.815	0.286	1.810
	T30	0.565	0.926	0.441	1.,080
	T45	0.913	0.778	0.239	7.300
	T60	0.739	0.963	0.263	9.500
	T90	0.826	0.889	0.206	6.220

Sensitivity	73.91%
Specificity	88.89%
False positive (error type I)	11.11%
False negative (error type II)	26.09%
Prevalence	0.460 or 46%
Test positive predictive value	94.4%
Test negative predictive value	81.25%
Accuracy	0.86 or 86%
Positive likelihood ratio	19.96
Negative likelihood ratio	0.27

Brasil