Urinary phenylacetylglutamine as dosing biomarker for patients with urea cycle disorders.

UNLABELLED: We have analyzed pharmacokinetic data for glycerol phenylbutyrate (also GT4P or HPN-100) and sodium phenylbutyrate with respect to possible dosing biomarkers in patients with urea cycle disorders (UCD). STUDY DESIGN: These analyses are based on over 3000 urine and plasma data points from 54 adult and 11 pediatric UCD patients (ages 6-17) who participated in three clinical studies comparing ammonia control and pharmacokinetics during steady state treatment with glycerol phenylbutyrate or sodium phenylbutyrate. All patients received phenylbutyric acid equivalent doses of glycerol phenylbutyrate or sodium phenylbutyrate in a cross over fashion and underwent 24-hour blood samples and urine sampling for phenylbutyric acid, phenylacetic acid and phenylacetylglutamine. RESULTS: Patients received phenylbutyric acid equivalent doses of glycerol phenylbutyrate ranging from 1.5 to 31.8 g/day and of sodium phenylbutyrate ranging from 1.3 to 31.7 g/day. Plasma metabolite levels varied widely, with average fluctuation indices ranging from 1979% to 5690% for phenylbutyric acid, 843% to 3931% for phenylacetic acid, and 881% to 1434% for phenylacetylglutamine. Mean percent recovery of phenylbutyric acid as urinary phenylacetylglutamine was 66.4 and 69.0 for pediatric patients and 68.7 and 71.4 for adult patients on glycerol phenylbutyrate and sodium phenylbutyrate, respectively. The correlation with dose was strongest for urinary phenylacetylglutamine excretion, either as morning spot urine (r = 0.730, p < 0.001) or as total 24-hour excretion (r = 0.791 p<0.001), followed by plasma phenylacetylglutamine AUC(24-hour), plasma phenylacetic acid AUC(24-hour) and phenylbutyric acid AUC(24-hour). Plasma phenylacetic acid levels in adult and pediatric patients did not show a consistent relationship with either urinary phenylacetylglutamine or ammonia control. CONCLUSION: The findings are collectively consistent with substantial yet variable pre-systemic (1st pass) conversion of phenylbutyric acid to phenylacetic acid and/or phenylacetylglutamine. The variability of blood metabolite levels during the day, their weaker correlation with dose, the need for multiple blood samples to capture trough and peak, and the inconsistency between phenylacetic acid and urinary phenylacetylglutamine as a marker of waste nitrogen scavenging limit the utility of plasma levels for therapeutic monitoring. By contrast, 24-hour urinary phenylacetylglutamine and morning spot urine phenylacetylglutamine correlate strongly with dose and appear to be clinically useful non-invasive biomarkers for compliance and therapeutic monitoring.

Tyrosine supplementation in phenylketonuria: diurnal blood tyrosine levels and presumptive brain influx of tyrosine and other large neutral amino acids.

UNLABELLED: Tyrosine supplementation has not consistently been found to improve neuropsychologic function in phenylketonuria (PKU), possibly because of failure to achieve adequate levels of tyrosine in the brain. OBJECTIVES: To evaluate blood levels achieved after tyrosine supplementation in treated PKU and calculate brain influxes of tyrosine and other large neutral amino acids before and with tyrosine supplementation. STUDY DESIGN: Ten subjects with PKU receiving a phenylalanine-restricted diet were studied over 48 hours; each received tyrosine supplementation (300 mg/kg) on day 2. Plasma phenylalanine and tyrosine were measured every 2 hours, and all free amino acids were measured every 6 hours. Brain influxes of tyrosine and other large neutral amino acids were calculated. RESULTS: Plasma tyrosine levels were low normal at baseline. With supplementation there was a substantial but unsustained rise in plasma tyrosine. Calculated brain influx of tyrosine was 27% +/- 19% of normal before supplementation, increasing to 90% +/- 58% of normal with supplementation. Nevertheless, calculated influx remained less than 70% of normal at 50% of the time points. The calculated brain influxes of all other large neutral amino acids except tryptophan were 20% to 40% of normal before and with tyrosine supplementation. CONCLUSIONS: Tyrosine supplementation in the diet for PKU produces marked but nonsustained increases in plasma tyrosine levels, with calculated brain influx that often remains suboptimal. This could explain the lack of consistent neuropsychologic benefit with tyrosine supplementation.

Urinary lactate excretion to monitor the efficacy of treatment of type I glycogen storage disease.

The purpose of this study was to investigate the usefulness of urinary lactate measurements to assess the adequacy of dietary treatment in patients with type I glycogen storage disease (GSD-I). We determined the correlation of urine and blood lactate concentrations in 21 GSD-I patients during 24-h admissions to the General Clinical Research Center (GCRC) during which hourly blood samples and aliquots of every void were obtained. In all but 1 patient, we found a good correlation between blood lactate concentrations and urinary lactate excretion. One patient did not excrete lactate in significant amounts despite elevated blood lactate concentrations. In 17 patients, the highest blood lactate concentrations occurred during the night. Markedly elevated nighttime average blood lactate concentrations above 3.5 mmol/l resulted in a urinary lactate concentration above the normal limit of 0.067 mmol/mmol creatinine in the first morning urine specimen. Mildly elevated nighttime blood lactate concentrations (between 2.2 and 3.5 mmol/l) led to urinary lactate concentrations that were either normal or moderately elevated. All patients with normal blood lactate concentrations during the night also had normal first morning urinary lactate concentrations. The degree of urinary lactate excretion in relation to blood lactate concentrations varied by individual. Urinary filter paper specimens, collected at home during the night and in the morning and mailed to the laboratory, were used to monitor the dietary compliance of 5 GSD-I patients at home over a period of 6 to 9 weeks prior to their GCRC admissions. These data suggested variable degrees of dietary control. In conclusion, the urinary lactate concentration is a useful parameter to monitor therapy of GSD-I patients at home. To be interpretable, the baseline urinary lactate concentration in relation to the blood lactate concentration has to be determined.

Quality of life assessment in adults with type 1 Gaucher disease.

The effect of enzyme replacement therapy on health-related quality of life in 25 adults with type 1 Gaucher disease was investigated over a 2-year period. Quality of life was assessed using the SF-36 Health Survey (SF-36). Psychological functioning was assessed using the Symptom Checklist--90R. The results indicated significant improvement in 7 of 8 SF scale scores beginning at 18 months of therapy (P < 0.05 to 0.001). The SF scale showing improvement first was Vitality (energy level and fatigue) at 6 months of therapy (P < 0.01). The SF-36 scales showing the largest improvements were Role-Physical and Social Functioning (P < 0.001). Compared to the general US adult population, the study population's health profile was significantly lower prior to starting therapy but by 24 months of therapy there were no differences between the two. No differences were found in psychological functioning compared to a US adult normative group at the start of therapy. However, within the study population there was significant improvement in mood and global functioning and fewer psychological symptoms reported at 24 months of therapy. The findings indicate that enzyme replacement therapy for type 1 Gaucher disease has a positive impact on health-related quality of life from the patient's perspective.

A GC/MS/MS screening method for multiple organic acidemias from urine specimens.

A gas chromatography tandem mass spectrometry method using an ion trap GC/MS system was developed to quickly screen urine samples for 14 organic acids associated with multiple organic acidemias. The following organic acids are used as diagnostic markers: methylmalonic acid, glutaric acid, 2-ketoisocaproic acid, succinylacetone, 3-methylcrotonylglycine, tiglylglycine, isovalerylglycine, fumaric acid, butyrylglycine, propionylglycine, hexanoylglycine, adipic acid, suberic acid, and sebacic acid. 2-ketocaproic acid is used as an internal standard. The samples are prepared using a solid-phase extraction and converted to trimethylsilyl derivatives. The extraction efficiency for the 14 compounds is between 57 and 106%. A derivatized standard mixture of the 14 markers is run prior to the patient samples to determine the accurate absolute and relative retention times. The samples are then injected and the product ion spectra monitored. For data analysis, one characteristic product ion plot is extracted for each of the 14 marker compounds, and the presence of a peak with the expected retention time is determined. The areas of the product ion peaks are compared with the reference range determined from 30 normal controls. Ten samples of patients with known organic acidemias were measured. For all patients, diagnostic peaks at the expected retention times of at least five times the upper limit of the reference range were detected. The method, with its relatively fast sample preparation, short 10.0 min run time and simple data analysis, is suitable for use as a quick metabolic screen of very sick patients in whom there is concern regarding the possibility of a treatable inborn error.

Quantification of glutaric acid by isotope dilution mass spectrometry for patients with glutaric acidemia type I: selected ion monitoring vs. selected ion storage.

An isotope dilution mass spectrometric assay for the quantification of glutaric acid in urine and serum samples was developed. The performance of a quadrupole mass filter (QMF) gas chromatography-mass spectrometry (GC-MS) instrument, operated in the selected ion monitoring mode, and a quadrupole ion trap (QIT) GC/MS instrument, operated in the selected ion storage mode, was compared. Both instruments gave linear standard curves with glutaric acid concentrations between 0.19 and 3.8 microM. The average coefficients of correlation were 0.9998 and 0.9993 for the QMF and the QIT system, respectively. There was good agreement between the glutaric acid concentrations measured with the two instruments. The run-to-run precision was between 1.2 and 3.7% and between 6.2 and 8.6%, the average recovery of glutaric acid in urine and serum samples was 96 and 103% with the QMF and QIT instrument, respectively. We conclude that although the QMF has a slightly better performance, both instruments can be used to reliably measure glutaric acid concentrations from urine and serum patient samples.

Reversal of severe hypertrophic cardiomyopathy and excellent neuropsychologic outcome in very-long-chain acyl-coenzyme A dehydrogenase deficiency.

Very-long-chain acyl-coenzyme A dehydrogenase (VLCAD) deficiency is a disorder of fatty acid beta oxidation that reportedly has high rates of morbidity and mortality. We describe the outcome of a 5-year-old girl with VLCAD deficiency who was first seen at 5 months of age with severe hypertrophic cardiomyopathy, hepatomegaly, encephalopathy, and hypotonia. Biochemical studies indicated VLCAD deficiency caused by a stable yet inactive enzyme. Molecular genetic analysis of her VLCAD gene revealed a T1372C (F458L) missense mutation and a 1668 ACAG 1669 splice site mutation. After initial treatment with intravenous glucose and carnitine, the patient has thrived on a low-fat diet supplemented with medium-chain triglyceride oil and carnitine and avoidance of fasting. Her ventricular hypertrophy resolved significantly over 1 year, and cognitively, she is in the superior range for age. Clinical recognition of VLCAD deficiency is important because it is one of the few directly treatable causes of cardiomyopathy in children.

Clinical approach to genetic cardiomyopathy in children.

BACKGROUND: Cardiomyopathy (CM) remains one of the leading cardiac causes of death in children, although in the majority of cases, the cause is unknown. To have an impact on morbidity and mortality, attention must shift to etiology-specific treatments. The diagnostic evaluation of children with CM of genetic origin is complicated by the large number of rare genetic causes, the broad range of clinical presentations, and the array of specialized diagnostic tests and biochemical assays. METHODS AND RESULTS: We present a multidisciplinary diagnostic approach to pediatric CM of genetic etiology. We specify criteria for abnormal left ventricular systolic performance and structure that suggest CM based on established normal echocardiographic measurements and list other indications to consider an evaluation for CM. We provide a differential diagnosis of genetic conditions associated with CM, classified as inborn errors of metabolism, malformation syndromes, neuromuscular diseases, and familial isolated CM disorders. A diagnostic strategy is offered that is based on the clinical presentation: biochemical abnormalities, encephalopathy, dysmorphic features or multiple malformations, neuromuscular disease, apparently isolated CM, and pathological specimen findings. Adjunctive treatment measures are recommended for severely ill patients in whom a metabolic cause of CM is suspected. A protocol is provided for the evaluation of moribund patients. CONCLUSIONS: In summary, we hope to assist pediatric cardiologists and other subspecialists in the evaluation of children with CM for a possible genetic cause using a presentation-based approach. This should increase the percentage of children with CM for whom a diagnosis can be established, with important implications for treatment, prognosis, and genetic counseling.

Oxidative phosphorylation defect associated with primary adrenal insufficiency.

An 18-month-old girl with an oxidative phosphorylation defect had neonatal onset of chronic lactic acidosis, lipid storage myopathy, bilateral cataracts, and primary adrenal insufficiency. Chronic lactic acidosis responded to treatment with dichloroacetate. Sequential muscle biopsies demonstrated resolution of the lipid storage myopathy associated with the return to normal muscle free carnitine levels. This case demonstrates a new clinical phenotype associated with a defect in oxidative phosphorylation and the need to consider mitochondrial disorders in the differential diagnosis of primary adrenal insufficiency in childhood.

Bilateral infantile cataractogenesis in a patient with deficiency of complex I, a mitochondrial electron transport chain enzyme.

Progressive bilateral cataracts developed in infancy in a 5-month-old girl with deficiency of complex I, a mitochondrial electron transport chain enzyme. In the newborn period, she had severe lactic acidosis and the diagnosis of complex I deficiency was confirmed by mitochondrial respiratory chain assay on muscle biopsy. By 5 months, she had completely opaque nuclear sclerotic cataracts, with loss of fixation and the red reflex. She underwent bilateral, sequential cataract extraction. The lens aspirate was submitted for cytologic analysis and electron microscopy, which revealed increased intracellular glycogen and swollen mitochondria. To our knowledge the association of complex I deficiency with cataracts in infancy has not been reported previously. The diagnosis of a respiratory chain enzyme defect in infancy is an indication for early ophthalmic evaluation to identify cataracts that may result in visual loss. Conversely, the recognition of cataracts in infants with unexplained neurologic disease or metabolic acidosis may necessitate further evaluation for metabolic etiologies, including mitochondrial disorders.

Lethal neonatal deficiency of carnitine palmitoyltransferase II associated with dysgenesis of the brain and kidneys.

We describe neonatal onset of a lethal multiorgan deficiency of carnitine palmitoyltransferase II (CPT II) associated with dysmorphic features, cardiomyopathy, and cystic dysplasia of the brain and kidneys. Concentrations of long-chain acylcarnitines were evaluated in blood and multiple tissues, diffuse lipid accumulation was present at autopsy, and a profound deficiency of CPT II activity was evident in heart, liver, muscle, and kidney tissue. This disorder constitutes another recognizable malformation syndrome with a metabolic basis. Deficiency of CPT II should be included in the differential diagnosis of patients with cystic renal dysplasia, dysmorphism, central nervous system malformations, and early death, along with glutaric acidemia type II, Zellweger syndrome, and other disorders in which peroxisomal beta-oxidation is impaired. The clinicopathologic similarities among these disorders raise the possibility that a common biochemical mechanism, namely the disruption of beta-oxidation of fatty acids, is responsible for the abnormal organogenesis.

A missense mutation (I278T) in the cystathionine beta-synthase gene prevalent in pyridoxine-responsive homocystinuria and associated with mild clinical phenotype.

Cystathionine beta-synthase (CBS) deficiency is an autosomal recessive disorder characterized by homocystinuria and multisystem clinical disease. Patients responsive to pyridoxine usually have a milder clinical phenotype than do nonresponsive patients, and we studied the molecular pathology of this disorder in an attempt to understand the molecular basis of the clinical variation. We previously reported a T833C transition in exon 8 causing a substitution of threonine for isoleucine at codon 278 (I278T). By PCR amplification and sequencing of exon 8 from genomic DNA we have now detected the I278T mutation in 7 of 11 patients with in vivo pyridoxine responsiveness and in 0 of 27 pyridoxine-nonresponsive patients. Two pyridoxine-responsive patients are homozygous and five are heterozygous for I278T. We have now observed the I278T mutation in 41% (9 of 22) of the independent alleles in pyridoxine-responsive patients of varied ethnic backgrounds. In two of the compound heterozygotes we identified a novel mutation (G139R and E144K) in the other allele. The finding that the two patients who are homozygous for I278T have only ectopia lentis and mild bone demineralization suggests that this mutation is associated with both in vivo pyridoxine responsiveness and mild clinical disease. Compound heterozygous patients who have one copy of this missense mutation are likely to retain some degree of pyridoxine responsiveness.

Neonatal-onset propionic acidemia: neurologic and developmental profiles, and implications for management.

OBJECTIVES: To document the clinical and neurodevelopmental profiles of a cohort of patients with neonatal-onset propionic acidemia and to determine the efficacy of current therapy with respect to outcome. METHOD: The clinical, neurologic, and developmental status of six patients was prospectively evaluated during a 15-month period. Previous clinical and biochemical data were ascertained from hospital records to determine longitudinal nutritional status, number of episodes of hyperammonemia with ketoacidosis, and developmental performance with respect to age. RESULTS: No deaths resulted from propionic acidemia since the identification of the oldest patient in the series in 1980. Therapeutic intervention (e.g., gastrostomy tube feeding) resulted in improved nutritional status and possibly contributed to improved survival. All children had hypotonia, resulting in a significant effect on motor development; however, focal neurologic deficits and evidence of movement or seizure disorder were absent. Mild cortical atrophy was evident on cranial magnetic resonance imaging in four patients. All children, including two patients with no significant episodes of hyperammonemia and normal growth since the neonatal period, had a mild to moderate degree of intellectual impairment. CONCLUSIONS: The results of our study suggest that current therapy for neonatal-onset propionic acidemia is associated with improved survival and nutritional status, and an absence of focal neurologic deficits. However, hypotonia and cognitive delay were still present, even in children with "optimal" metabolic control. Additional therapeutic advances are required to improve the developmental and cognitive outcome.