ABSTRACT
Patients with inborn errors of metabolism causing fasting intolerance can experience acute metabolic decompensations. Long-term data on outcomes using emergency letters are lacking. This is a retrospective, observational, single-center study of the use of emergency letters based on a generic emergency protocol in patients with hepatic glycogen storage diseases (GSD) or fatty acid oxidation disorders (FAOD). Data on hospital admissions, initial laboratory results, and serious adverse events were collected. Subsequently, the website www.emergencyprotocol.net was generated in the context of the CONNECT MetabERN eHealth project following multiple meetings, protocol revisions, and translations. Representing 470 emergency protocol years, 127 hospital admissions were documented in 54/128 (42%) patients who made use of emergency letters generated based on the generic emergency protocol. Hypoglycemia (here defined as glucose concentration < 3.9 mmol/L) was reported in only 15% of hospital admissions and was uncommon in patients with ketotic GSD and patients with FAOD aged >5 years. Convulsions, coma, or death was not documented. By providing basic information, emergency letters for individual patients with hepatic GSD or the main FAOD can be generated at www.emergencyprotocol.net, in nine different languages. Generic emergency protocols are safe and easy for home management by the caregivers and the first hour in-hospital management to prevent metabolic emergencies in patients with hepatic GSD and medium-chain Acyl CoA dehydrogenase deficiency. The website www.emergencyprotocol.net is designed to support families and healthcare providers to generate personalized emergency letters for patients with hepatic GSD and the main FAOD.
Subject(s)
Emergency Treatment/methods , Glycogen Storage Disease Type I/metabolism , Hypoglycemia/therapy , Lipid Metabolism, Inborn Errors/metabolism , Telemedicine , Adolescent , Adult , Child , Child, Preschool , Fasting , Fatty Acids/metabolism , Female , Glycogen Storage Disease Type I/physiopathology , Humans , Hypoglycemia/etiology , Infant , Infant, Newborn , Lipid Metabolism, Inborn Errors/physiopathology , Male , Middle Aged , Oxidation-Reduction , Retrospective Studies , Young AdultABSTRACT
BACKGROUND: Phenylketonuria (PKU) is an inborn error of phenylalanine (Phe) metabolism. Besides dietary treatment, some patients are responsive to and treated with tetrahydrobiopterin (BH4). Our primary objective was to examine whether the 48-hour BH4 loading test misses BH4-responsive PKU patients. Secondary, we assessed if it would be beneficial to 1) use a cut-off value of 20% Phe reduction instead of commonly used 30%, and 2) extend the loading test to 7 days. METHODS: 24 patients with a 20-30% decrease of blood Phe levels during their initial 48-hour BH4 loading test or at least one mutation associated with long-term BH4 responsiveness, were invited to participate. 22 of them underwent the 7-day BH4 loading test. During the BH4 loading test, BH4 was administered orally once daily for 7 days (20 mg/kg/day). Blood samples on filter paper were collected at 13 time points. Potential BH4 responders (≥20% decrease in blood Phe concentrations at ≥1 moment within the first 48 h or ≥30% at ≥1 moment during the entire test) underwent a treatment trial to assess true long-term responsiveness (≥30% decrease of Phe levels compared to baseline and/or ≥50% increase in natural protein tolerance in accordance with the Dutch guidelines before 2017). The duration of the treatment trial varied from 2 to 18 months. RESULTS: Of the 22 patients who completed the 7-day BH4 loading test, 2 were excluded, 8 had negative tests and 12 were considered to be potential BH4 responders. Of these 12 potential BH4-responsive PKU patients, 5 turned out to be false positive, 6 true-responder and 1 was withdrawn. CONCLUSION: Even though the 48-hour BH4 loading test has proven its efficacy in the past, a full week may be necessary to detect all responders. So, if blood Phe concentrations during the 48-hour BH4 test shows a clear tendency, but not sufficient decrease, a full week (with only measurements each 24 h) could be offered. A threshold of ≥20% decrease within 48 h is not useful for predicting true BH4 responsiveness.
Subject(s)
Biopterins/analogs & derivatives , Diagnostic Tests, Routine/methods , Phenylalanine/blood , Phenylketonurias/diagnosis , Phenylketonurias/drug therapy , Adolescent , Adult , Biopterins/administration & dosage , Child , Female , Genotype , Humans , Male , Middle Aged , Mutation , Phenylketonurias/diet therapy , Phenylketonurias/genetics , Time FactorsABSTRACT
OBJECTIVE: This study aimed to investigate and improve the usefulness of the 48-hour BH4 loading test and to assess genotype for BH4 responsiveness prediction, using the new definition of BH4 responsiveness from the European guidelines, as well as an amended definition. METHOD: Applying the definition of the European guidelines (≥100% increase in natural protein tolerance) and an amended definition (≥100% increase in natural protein tolerance or tolerating a safe natural protein intake) to a previous dataset, we first assessed the positive predictive value (PPV) of the 48-hour BH4 loading test using a cutoff value of 30%. Then, we tried to improve this PPV by using different cutoff values and separate time points. Last, using the BIOPKU database, we compared predicted BH4 responsiveness (according to genotype) and genotypic phenotype values (GPVs) in BH4 -responsive and BH4 -unresponsive patients. RESULTS: The PPV of the 48-hour loading test was 50.0% using the definition of the European guidelines, and 69.4% when applying the amended definition of BH4 responsiveness. Higher cutoff values led to a higher PPV, but resulted in an increase in false-negative tests. Parameters for genotype overlapped between BH4 -responsive and BH4 -unresponsive patients, although BH4 responsiveness was not observed in patients with a GPV below 2.4. CONCLUSION: The 48-hour BH4 loading test is not as useful as previously considered and cannot be improved easily, whereas genotype seems mainly helpful in excluding BH4 responsiveness. Overall, the definition of BH4 responsiveness and BH4 responsiveness testing require further attention.
Subject(s)
Phenylketonurias/diagnosis , Phenylketonurias/metabolism , Practice Guidelines as Topic , Adolescent , Biopterins/analogs & derivatives , Biopterins/metabolism , Child , Europe , Female , Genotype , Humans , Male , Phenylketonurias/genetics , Predictive Value of Tests , Young AdultABSTRACT
INTRODUCTION: In hereditary tyrosinemia type 1 (HT1) patients, the dose of NTBC that leads to the absence of toxic metabolites such as succinylacetone (SA) is still unknown. Therefore, the aims of this study were to investigate the variation and concentrations of 2-(2-nitro-4-trifluormethyl-benzyl)-1,3-cyclohexanedione (NTBC) during the day in relation to the detection of SA, while comparing different dosing regimens. METHODS: All patients were treated with NTBC (mean 1.08 ± 0.34 mg/kg/day) and a low phenylalanine-tyrosine diet. Thirteen patients received a single dose of NTBC and five patients twice daily. Home bloodspots were collected four times daily for three consecutive days measuring NTBC and SA concentrations. Statistical analyses were performed by using mixed model analyses and generalized linear mixed model analyses to study variation and differences in NTBC concentrations and the correlation with SA, respectively. RESULTS: NTBC concentrations varied significantly during the day especially if NTBC was taken at breakfast only (p = 0.026), although no significant difference in NTBC concentrations between different dosing regimens could be found (p = 0.289). Momentary NTBC concentrations were negatively correlated with SA (p < 0.001). Quantitatively detectable SA was only found in subjects with once daily administration of NTBC and associated with momentary NTBC concentrations <44.3 µmol/l. DISCUSSION: NTBC could be less stable than previously considered, thus dosing NTBC once daily and lower concentrations may be less adequate. Further research including more data is necessary to establish the optimal dosing of NTBC.
Subject(s)
Cyclohexanones/administration & dosage , Nitrobenzoates/administration & dosage , Tyrosinemias/drug therapy , Adolescent , Child , Child, Preschool , Chromatography, High Pressure Liquid , Cyclohexanones/blood , Cyclohexanones/pharmacokinetics , Diet, Protein-Restricted , Dried Blood Spot Testing , Drug Administration Schedule , Drug Monitoring/methods , Female , Humans , Infant , Male , Nitrobenzoates/blood , Nitrobenzoates/pharmacokinetics , Prospective Studies , Tandem Mass Spectrometry , Time Factors , Treatment Outcome , Tyrosinemias/blood , Tyrosinemias/diagnosis , Young AdultABSTRACT
BACKGROUND: Severe intellectual disability and growth impairment have been overcome by the success of early and continuous treatment of patients with phenylketonuria (PKU). However, there are some reports of obesity, particularly in women, suggesting that this may be an important comorbidity in PKU. It is becoming evident that in addition to acceptable blood phenylalanine control, metabolic dieticians should regard weight management as part of routine clinical practice. SUMMARY: It is important for practitioners to differentiate the 3 levels for overweight interpretation: anthropometry, body composition and frequency and severity of associated metabolic comorbidities. The main objectives of this review are to suggest proposals for the minimal standard and gold standard for the assessment of weight management in PKU. While the former aims to underline the importance of nutritional status evaluation in every specialized clinic, the second objective is important in establishing an understanding of the breadth of overweight and obesity in PKU in Europe. KEY MESSAGES: In PKU, the importance of adopting a European nutritional management strategy on weight management is highlighted in order to optimize long-term health outcomes in patients with PKU.
Subject(s)
Obesity/therapy , Overweight/therapy , Phenylketonurias/therapy , Anthropometry , Body Composition , Body Mass Index , Body Weight Maintenance , Comorbidity , Europe/epidemiology , Humans , Life Style , Nutritional Status , Obesity/blood , Overweight/blood , Phenylalanine/blood , Phenylketonurias/bloodABSTRACT
α-Synuclein (α-syn), a small protein that has the intrinsic propensity to aggregate, is implicated in several neurodegenerative diseases including Parkinson's disease (PD), dementia with Lewy bodies (DLB), and multiple system atrophy (MSA), which are collectively known as synucleinopathies. Genetic, pathological, biochemical, and animal modeling studies provided compelling evidence that α-syn aggregation plays a key role in the pathogenesis of PD and related synucleinopathies. It is therefore of utmost importance to develop reliable tools that can detect the aggregated forms of α-syn. We describe here the generation and characterization of six novel conformation-specific monoclonal antibodies that recognize specifically α-syn aggregates but not the soluble, monomeric form of the protein. The antibodies described herein did not recognize monomers or fibrils generated from other amyloidogenic proteins including ß-syn, γ-syn, ß-amyloid, tau protein, islet amyloid polypeptide and ABri. Interestingly, the antibodies did not react to overlapping linear peptides spanning the entire sequence of α-syn, confirming further that they only detect α-syn aggregates. In immunohistochemical studies, the new conformation-specific monoclonal antibodies showed underappreciated small micro-aggregates and very thin neurites in PD and DLB cases that were not observed with generic pan antibodies that recognize linear epitope. Furthermore, employing one of our conformation-specific antibodies in a sandwich based ELISA, we observed an increase in levels of α-syn oligomers in brain lysates from DLB compared to Alzheimer's disease and control samples. Therefore, the conformation-specific antibodies portrayed herein represent useful tools for research, biomarkers development, diagnosis and even immunotherapy for PD and related pathologies.
Subject(s)
Antibodies, Monoclonal/immunology , Brain/metabolism , alpha-Synuclein/chemistry , alpha-Synuclein/immunology , Adaptor Proteins, Signal Transducing , Alzheimer Disease/metabolism , Amyloid beta-Peptides/metabolism , Animals , Antibodies, Monoclonal/isolation & purification , Antibodies, Monoclonal/metabolism , Brain/pathology , Escherichia coli , Islet Amyloid Polypeptide/metabolism , Lewy Body Disease/metabolism , Lewy Body Disease/pathology , Membrane Glycoproteins/metabolism , Mice , Neoplasm Proteins/immunology , Neoplasm Proteins/metabolism , Parkinson Disease/metabolism , Parkinson Disease/pathology , Peptide Fragments/metabolism , Protein Conformation , Protein Multimerization , Recombinant Proteins/chemistry , Recombinant Proteins/immunology , Recombinant Proteins/metabolism , alpha-Synuclein/metabolism , beta-Synuclein/immunology , beta-Synuclein/metabolism , gamma-Synuclein/immunology , gamma-Synuclein/metabolism , tau Proteins/metabolismABSTRACT
BACKGROUND AND OBJECTIVES: Children of parents with an anxiety disorder are at elevated risk for developing an anxiety disorder themselves. According to cognitive theories, a possible risk factor is the development of schema-related associations. This study is the first to investigate whether children of anxious parents display fear-related associations and whether these associations relate to parental anxiety. METHODS: 44 children of parents with panic disorder, 27 children of parents with social anxiety disorder, and 84 children of parents without an anxiety disorder filled out the SCARED-71, and the children performed an Affective Priming Task. RESULTS: We found partial evidence for disorder-specificity: When the primes were related to their parent's disorder and the targets were negative, the children of parents with panic disorder and children of parents with social anxiety disorder showed the lowest error rates related to their parents' disorder, but they did not have faster responses. We did not find any evidence for the expected specificity in the relationship between the parents' or the children's self-reported anxiety and the children's fear-related associations, as measured with the APT. LIMITATIONS: Reliability of the Affective Priming Task was moderate, and power was low for finding small interaction effects. CONCLUSIONS: Whereas clearly more research is needed, our results suggest that negative associations may qualify as a possible vulnerability factor for children of parents with an anxiety disorder.
Subject(s)
Anxiety Disorders , Child of Impaired Parents , Fear , Parents , Humans , Male , Female , Fear/physiology , Child , Child of Impaired Parents/psychology , Adult , Adolescent , Association , Psychiatric Status Rating ScalesABSTRACT
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 (n = 625, 48%), followed by mild PKU (n = 357, 27%) and hyperphenylalaninemia (HPA) (n = 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 (p < 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 (p = 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; p = 0.005), adolescents (13-18 years; 62% in females vs. 59% in males; p = 0.034) and adults (31-40 years; 65% in females vs. 41% in males; p < 0.001 and >41 years; 43% in females vs. 28% in males; p < 0.001). Patients treated with sapropterin (n = 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%; p < 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 (p < 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.
Subject(s)
Phenylalanine , Phenylketonurias , Humans , Phenylketonurias/blood , Phenylalanine/blood , Male , Adolescent , Child , Female , Child, Preschool , Europe , Adult , Young Adult , Retrospective Studies , Infant , Middle Aged , Turkey/epidemiologyABSTRACT
In phenylketonuria (PKU), natural protein intake is thought to increase with age, particularly during childhood and adolescence. Longitudinal dietary intake data are scarce and lifelong phenylalanine tolerance remains unknown. Nine centres managing PKU in Europe and Turkey participated in a retrospective study. Data were collected from dietetic records between 2012 and 2018 on phenylalanine (Phe), natural protein, and protein substitute intake. A total of 1323 patients (age range: 1-57 y; 51% male) participated. Dietary intake data were available on 1163 (88%) patients. Patient numbers ranged from 59 to 320 in each centre. A total of 625 (47%) had classical PKU (cPKU), n = 357 (27%) had mild PKU (mPKU), n = 325 (25%) had hyperphenylalaninemia (HPA), and n = 16 (1%) were unknown. The mean percentage of blood Phe levels within target ranged from 65 ± 54% to 88 ± 49%. When intake was expressed as g/day, the mean Phe/natural protein and protein equivalent from protein substitute gradually increased during childhood, reaching a peak in adolescence, and then remained consistent during adulthood. When intake was expressed per kg body weight (g/kg/day), there was a decline in Phe/natural protein, protein equivalent from protein substitute, and total protein with increasing age. Overall, the mean daily intake (kg/day) was as follows: Phe, 904 mg ± 761 (22 ± 23 mg/kg/day), natural protein 19 g ± 16 (0.5 g/kg/day ± 0.5), protein equivalent from protein substitute 39 g ± 22 (1.1 g/kg/day ± 0.6), and total protein 59 g ± 21 (1.7 g/kg/day ± 0.6). Natural protein tolerance was similar between males and females. Patients with mPKU tolerated around 50% less Phe/natural protein than HPA, but 50% more than cPKU. Higher intakes of natural protein were observed in Southern Europe, with a higher prevalence of HPA and mPKU compared with patients from Northern European centres. Natural protein intake doubled with sapropterin usage. In sapropterin-responsive patients, 31% no longer used protein substitutes. Close monitoring and optimisation of protein intake prescriptions are needed, along with future guidelines specifically for different age groups and severities.
Subject(s)
Phenylalanine , Phenylketonurias , Humans , Phenylketonurias/diet therapy , Phenylketonurias/blood , Male , Adolescent , Female , Child, Preschool , Child , Europe/epidemiology , Phenylalanine/blood , Phenylalanine/administration & dosage , Adult , Retrospective Studies , Young Adult , Infant , Middle Aged , Age Factors , Longitudinal Studies , Dietary Proteins/administration & dosage , Severity of Illness Index , Turkey/epidemiologySubject(s)
Biomarkers/blood , Biopterins/analogs & derivatives , Phenylketonurias/diet therapy , Adolescent , Adult , Biopterins/administration & dosage , Biopterins/adverse effects , Biopterins/genetics , Biopterins/metabolism , Body Mass Index , Child , Child, Preschool , Female , Humans , Infant , Male , Phenylalanine Hydroxylase/blood , Phenylketonurias/blood , Phenylketonurias/pathology , Young AdultABSTRACT
In phenylketonuria (PKU), natural protein tolerance is defined as the maximum natural protein intake maintaining a blood phenylalanine (Phe) concentration within a target therapeutic range. Tolerance is affected by several factors, and it may differ throughout a person's lifespan. Data on lifelong Phe/natural protein tolerance are limited and mostly reported in studies with low subject numbers. This systematic review aimed to investigate how Phe/natural protein tolerance changes from birth to adulthood in well-controlled patients with PKU on a Phe-restricted diet. Five electronic databases were searched for articles published until July 2020. From a total of 1334 results, 37 articles met the eligibility criteria (n = 2464 patients), and 18 were included in the meta-analysis. The mean Phe (mg/day) and natural protein (g/day) intake gradually increased from birth until 6 y (at the age of 6 months, the mean Phe intake was 267 mg/day, and natural protein intake was 5.4 g/day; at the age of 5 y, the mean Phe intake was 377 mg/day, and the natural protein intake was 8.9 g/day). However, an increase in Phe/natural protein tolerance was more apparent at the beginning of late childhood and was >1.5-fold that of the Phe tolerance in early childhood. During the pubertal growth spurt, the mean natural protein/Phe tolerance was approximately three times higher than in the first year of life, reaching a mean Phe intake of 709 mg/day and a mean natural protein intake of 18 g/day. Post adolescence, a pooled analysis could only be performed for natural protein intake. The mean natural protein tolerance reached its highest (32.4 g/day) point at the age of 17 y and remained consistent (31.6 g/day) in adulthood, but limited data were available. The results of the meta-analysis showed that Phe/natural protein tolerance (expressed as mg or g per day) increases with age, particularly at the beginning of puberty, and reaches its highest level at the end of adolescence. This needs to be interpreted with caution as limited data were available in adult patients. There was also a high degree of heterogeneity between studies due to differences in sample size, the severity of PKU, and target therapeutic levels for blood Phe control.
Subject(s)
Phenylalanine , Phenylketonurias , Child , Child, Preschool , Adolescent , Adult , Humans , Infant , Databases, Factual , Immune Tolerance , LongevityABSTRACT
Background: The metabolic dietitian/nutritionist (hereafter 'dietitian') plays an essential role in the nutritional management of patients with phenylketonuria (PKU), including those on pegvaliase. Currently, more educational support and clinical experience is needed to ensure that dietitians are prepared to provide optimal nutritional management and counselling of pegvaliase-treated patients. Methods: Via a face-to-face data-review meeting, followed by a virtual consolidation meeting, a group of expert dietitians and one paediatrician discussed and developed a series of recommendations on the nutritional evaluation and management of patients receiving pegvaliase. The consensus group consisted of 10 PKU experts: six dietitians and one paediatrician from Europe and three dietitians from the US. One European and three US dietitians had experience with pegvaliase-treated patients. Results: The consensus group recommended that a physician, dietitian and nurse are part of the pegvaliase treatment team. Additionally, a psychologist/counsellor should be included if available. Practical proposals for the nutritional evaluation of pegvaliase-treated patients at baseline, during the induction and titration phases and for long-term maintenance were developed. The consensus group suggested assessment of blood Phe at least monthly or every 2 weeks in the event of low blood Phe (i.e., blood Phe <30 µmol/L). It may be appropriate to increase blood Phe monitoring when adjusting protein intake and/or pegvaliase dose. It was recommended that natural protein intake is increased by 10-20 g increments if blood Phe concentrations decrease to <240 µmol/L in patients who are not meeting the dietary reference intake for natural protein of 0.8 g/kg. It was proposed that with pegvaliase treatment blood Phe levels could be maintained <240 µmol/L but more evidence on the safety of achieving physiological blood Phe levels is necessary before any recommendation on the lower blood Phe target can be given. Finally, both patients and dietitians should have access to educational resources to optimally support patients receiving pegvaliase. Conclusion: This practical road map aims to provide initial recommendations for dietitians monitoring patients with PKU prescribed pegvaliase. Given that practical experience with pegvaliase is still limited, nutritional recommendations will require regular updating once more evidence is available and clinical experience evolves.
ABSTRACT
Phenylketonuria and tyrosinemia type 1 are treated with dietary phenylalanine (Phe) restriction. Aspartame is a Phe-containing synthetic sweetener used in many products, including many 'regular' soft drinks. Its amount is (often) not declared; therefore, patients are advised not to consume aspartame-containing foods. This study aimed to determine the variation in aspartame concentrations and its Phe-containing degradation products in aspartame-containing soft drinks. For this, an LC-MS/MS method was developed for the analysis of aspartame, Phe, aspartylphenylalanine, and diketopiperazine in soft drinks. In total, 111 regularly used soft drinks from 10 European countries were analyzed. The method proved linear and had an inter-assay precision (CV%) below 5% for aspartame and higher CVs% of 4.4-49.6% for the degradation products, as many concentrations were at the limit of quantification. Aspartame and total Phe concentrations in the aspartame-containing soft drinks varied from 103 to 1790 µmol/L (30-527 mg/L) and from 119 to 2013 µmol/L (20-332 mg/L), respectively, and were highly variable among similar soft drinks bought in different countries. Since Phe concentrations between drinks and countries highly vary, we strongly advocate the declaration of the amount of aspartame on soft drink labels, as some drinks may be suitable for consumption by patients with Phe-restricted diets.
Subject(s)
Aspartame/analysis , Carbonated Beverages/analysis , Phenylalanine/analysis , Aspartame/chemistry , Carbonated Beverages/standards , Chromatography, Liquid/methods , Diketopiperazines/analysis , Diketopiperazines/chemistry , Dipeptides/analysis , Dipeptides/chemistry , Europe , Food Safety , Humans , Limit of Detection , Phenylalanine/chemistry , Phenylketonurias , Reproducibility of Results , Tandem Mass Spectrometry/methodsABSTRACT
BACKGROUND: This study investigated the agreement between various dried blood spot (DBS) and venous blood sample measurements of phenylalanine and tyrosine concentrations in Phenylketonuria (PKU) and Tyrosinemia type 1 (TT1) patients. STUDY DESIGN: Phenylalanine and tyrosine concentrations were studied in 45 PKU/TT1 patients in plasma from venous blood in lithium heparin (LH) and EDTA tubes; venous blood from LH and EDTA tubes on a DBS card; venous blood directly on a DBS card; and capillary blood on a DBS card. Plasma was analyzed with an amino acid analyzer and DBS were analyzed with liquid chromatography-mass spectrometry. Agreement between different methods was assessed using Passing and Bablok fit and Bland Altman analyses. RESULTS: In general, phenylalanine concentrations in LH plasma were comparable to capillary DBS, whereas tyrosine concentrations were slightly higher in LH plasma (constant bias of 6.4 µmol/L). However, in the low phenylalanine range, most samples had higher phenylalanine concentrations in DBS compared to LH plasma. Remarkably, phenylalanine and tyrosine in EDTA plasma were higher compared to all other samples (slopes ranging from 7 to 12%). No differences were observed when comparing capillary DBS to other DBS. CONCLUSIONS: Overall agreement between plasma and DBS is good. However, bias is specimen- (LH vs EDTA), and possibly concentration- (low phenylalanine) dependent. Because of the overall good agreement, we recommend the use of a DBS-plasma correction factor for DBS measurement. Each laboratory should determine their own factor dependent on filter card type, extraction and calibration protocols taking the LH plasma values as gold standard.
Subject(s)
Phenylalanine , Phenylketonurias , Amino Acids , Dried Blood Spot Testing , Humans , TyrosineABSTRACT
High-sugar diets cause thirst, obesity, and metabolic dysregulation, leading to diseases including type 2 diabetes and shortened lifespan. However, the impact of obesity and water imbalance on health and survival is complex and difficult to disentangle. Here, we show that high sugar induces dehydration in adult Drosophila, and water supplementation fully rescues their lifespan. Conversely, the metabolic defects are water-independent, showing uncoupling between sugar-induced obesity and insulin resistance with reduced survival in vivo. High-sugar diets promote accumulation of uric acid, an end-product of purine catabolism, and the formation of renal stones, a process aggravated by dehydration and physiological acidification. Importantly, regulating uric acid production impacts on lifespan in a water-dependent manner. Furthermore, metabolomics analysis in a human cohort reveals that dietary sugar intake strongly predicts circulating purine levels. Our model explains the pathophysiology of high-sugar diets independently of obesity and insulin resistance and highlights purine metabolism as a pro-longevity target.
Subject(s)
Dehydration/chemically induced , Obesity/chemically induced , Sugars/adverse effects , Water/metabolism , Animals , Drosophila/physiology , Humans , Insulin Resistance , LongevityABSTRACT
There is an ongoing debate regarding the impact of phenylketonuria (PKU) and its treatment on growth. To date, evidence from studies is inconsistent, and data on the whole developmental period is limited. The primary aim of this systematic review was to investigate the effects of a phenylalanine (Phe)-restricted diet on long-term growth in patients with PKU. Four electronic databases were searched for articles published until September 2018. A total of 887 results were found, but only 13 articles met eligibility criteria. Only three studies had an adequate methodology for meta-analysis. Although the results indicate normal growth at birth and during infancy, children with PKU were significantly shorter and had lower weight for age than reference populations during the first four years of life. Impaired linear growth was observed until the end of adolescence in PKU. In contrast, growth impairment was not reported in patients with mild hyperphenylalaninemia, not requiring dietary restriction. Current evidence indicates that even with advances in dietary treatments, "optimal" growth outcomes are not attained in PKU. The majority of studies include children born before 1990s, so further research is needed to show the effects of recent dietary practices on growth in PKU.
Subject(s)
Child Development , Phenylketonurias , Body Height , Body Weight , Child, Preschool , Female , Humans , Infant , MaleABSTRACT
Background Phenylketonuria (PKU), a rare, inherited metabolic condition, is treated with a strict low-phenylalanine (Phe) diet, supplemented with Phe-free protein substitute. The optimal nutritional management of a sporting individual with PKU has not been described. Therefore, guidelines for the general athlete have to be adapted. Case presentation Three clinical scenarios of sporting patients with PKU are given, illustrating dietary adaptations to usual management and challenges to attain optimal sporting performance. Therefore, the main objectives of sports nutrition in PKU are to (1) maintain a high carbohydrate diet; (2) carefully monitor hydration status; and (3) give attention to the timing of protein substitute intake in the immediate post-exercise recovery phase. Optimal energy intake should be given prior to, during and post exercise training sessions or competition. Fortunately, a usual low-Phe diet is rich in carbohydrate, but attention is required on the types of special low-protein foods chosen. Acute exercise does not seem to influence blood Phe concentrations, but further evidence is needed. Summary Well-treated PKU patients should be able to participate in sports activities, but this is associated with increased nutritional requirements and dietary adjustments. Conclusions It should be the goal of all sporting patients with PKU to maintain good metabolic Phe control and attain maximal athletic performance.
Subject(s)
Biomarkers/analysis , Dietary Supplements , Exercise Therapy , Phenylketonurias/therapy , Adolescent , Adult , Female , Humans , Male , Phenylalanine/blood , Phenylketonurias/blood , Prognosis , Young AdultABSTRACT
OBJECTIVE: Children of parents with an anxiety disorder have a higher risk of developing an anxiety disorder than children of parents without an anxiety disorder. Parental anxiety is not regarded as a causal risk factor itself, but is likely to be mediated via other mechanisms, for example via cognitive factors. We investigated whether children of parents with an anxiety disorder would show an interpretation bias corresponding to the diagnosis of their parent. We also explored whether children's interpretation biases were explained by parental anxiety and/or children's levels of anxiety. METHOD: In total, 44 children of parents with a panic disorder (PD), 27 children of parents with a social anxiety disorder (SAD), 7 children of parents with SAD/PD, and 84 children of parents without an anxiety disorder (controls) participated in this study. Parents and children filled out the Screen for Child Anxiety Related Disorders (SCARED) questionnaire, and children performed two ambiguous scenario tasks: one with and one without video priming. RESULTS: Children of parents with PD displayed significantly more negative interpretations of panic scenarios and social scenarios than controls. Negative interpretations of panic scenarios were explained by parental PD diagnosis and children's anxiety levels. These effects were not found for children of parents with SAD. Priming did not affect interpretation. CONCLUSION: Our results showed that children of parents with PD have a higher chance of interpreting ambiguous situations more negatively than children of parents without anxiety disorders. More research is needed to study whether this negative bias predicts later development of anxiety disorders in children.
Subject(s)
Anxiety Disorders/psychology , Bias , Child of Impaired Parents/psychology , Parents/psychology , Child , Female , Humans , Male , Psychophysiology , Surveys and Questionnaires , Videotape Recording , Vulnerable PopulationsABSTRACT
Models of cognitive processing in anxiety disorders state that socially anxious children display several distorted cognitive processes that maintain their anxiety. The present study investigated the role of social threat thoughts and social skills perception in relation to childhood trait and state social anxiety. In total, 141 children varying in their levels of social anxiety performed a short speech task in front of a camera and filled out self-reports about their trait social anxiety, state anxiety, social skills perception and social threat thoughts. Results showed that social threat thoughts mediated the relationship between trait social anxiety and state anxiety after the speech task, even when controlling for baseline state anxiety. Furthermore, we found that children with higher trait anxiety and more social threat thoughts had a lower perception of their social skills, but did not display a social skills deficit. These results provide evidence for the applicability of the cognitive social anxiety model to children.
ABSTRACT
BACKGROUND: Treatment of hereditary tyrosinemia type 1 with nitisinone and phenylalanine and tyrosine restricted diet has largely improved outcome, but the best blood sampling time for assessment of metabolic control is not known. AIM: To study diurnal and day-to-day variation of phenylalanine and tyrosine concentrations in tyrosinemia type 1 patients. METHODS: Eighteen tyrosinemia type 1 patients aged >1 year (median age 7.9 years; range 1.6-20.7) were studied. Capillary blood samples were collected 4 times a day (T1: pre-breakfast, T2: pre-midday meal, T3: before evening meal, and T4: bedtime) for 3 days. Linear mixed-effect models were used to investigate diurnal and day-to-day variation of both phenylalanine and tyrosine. RESULTS: The coefficients of variation of phenylalanine and tyrosine concentrations were the lowest on T1 (13.8% and 14.1%, respectively). Tyrosine concentrations did not significantly differ between the different time points, but phenylalanine concentrations were significantly lower at T2 and T3 compared to T1 (50.1 µmol/L, 29.8 µmol/L, and 37.3 µmol/L, respectively). CONCLUSION: Our results indicated that for prevention of too low phenylalanine and too high tyrosine concentrations, measurement of phenylalanine and tyrosine pre-midday meal would be best, since phenylalanine concentrations are the lowest on that time point. Our results also indicated that whilst blood tyrosine concentrations were stable over 24 h, phenylalanine fluctuated. Day-to-day variation was most stable after an overnight fast for both phenylalanine and tyrosine. Therefore, in tyrosinemia type 1 patients the most reliable time point for measuring phenylalanine and tyrosine concentrations to enable interpretation of metabolic control is pre-breakfast.