Your search keyword '"Poll‐The, B. T."' showing total 13 results

1. Normal very-long-chain fatty acids in peroxisomal D-bifunctional protein deficiency: a diagnostic pitfall.

Author

Soorani-Lunsing RJ, van Spronsen FJ, Stolte-Dijkstra I, Wanders RJ, Ferdinandusse S, Waterham HR, Poll-The BT, and Rake JP

Subjects

Brain pathology, Consanguinity, Facies, Fatty Acids metabolism, Female, Fibroblasts metabolism, Homozygote, Humans, Infant, Magnetic Resonance Imaging, Mutation, Peroxisomal Multifunctional Protein-2, 17-Hydroxysteroid Dehydrogenases deficiency, Blood Chemical Analysis methods, Fatty Acids analysis, Hydro-Lyases deficiency, Metabolism, Inborn Errors diagnosis, Peroxisomal Disorders diagnosis, Peroxisomes metabolism

Abstract

We present a relatively mild case of peroxisomal D-bifunctional protein deficiency with inconsistent screening results in plasma for peroxisomal disorders.

Published

2005

2. The eye as a window to inborn errors of metabolism.

Author

Poll-The BT, Maillette de Buy Wenniger-Prick LJ, Barth PG, and Duran M

Subjects

Animals, Cataract etiology, Corneal Diseases etiology, Humans, Optic Nerve Diseases, Retinal Degeneration, Eye Diseases etiology, Metabolism, Inborn Errors complications

Abstract

Ocular manifestations in inborn errors of metabolism occur in many diseases and may be associated with any part of all eye components. In a minority of diseases it is possible to attribute the eye symptoms to a single hereditary pathogenetic mechanism. More often the aetiological relationship of the ocular defects to the metabolic disease is unknown. Diverse pathogenetic mechanisms may act via a common pathological pathway inducing ocular damage. The occurrence of eye abnormalities in metabolic disorders suggests that they are associated with direct toxic actions, errors of synthetic pathways or deficient energy metabolism. In this review, metabolic disorders with major abnormalities in the cornea, lens, retina and optic nerve are presented. In all cases, an appropriate combined approach by the ophthalmologist, paediatrician/neurologist, geneticist and clinical biochemist is the only way to diagnostic success.

Published

2003

3. Plasma pipecolic acid is frequently elevated in non-peroxisomal disease.

Author

Baas JC, van de Laar R, Dorland L, Duran M, Berger R, Poll-The BT, and de Koning TJ

Subjects

Biomarkers, False Positive Reactions, Humans, Pipecolic Acids cerebrospinal fluid, Retrospective Studies, Metabolism, Inborn Errors blood, Peroxisomal Disorders blood, Pipecolic Acids blood

Abstract

We reviewed our data on patients in whom plasma pipecolic acid was analysed. Mild to moderate elevations of pipecolic acid were frequently found in non-peroxisomal disorders and this should be taken into account when interpreting the laboratory data.

Published

2002

4. Continuing education in neurometabolic disorders--serine deficiency disorders.

Author

de Koning TJ, Poll-The BT, and Jaeken J

Subjects

Adolescent, Amino Acids blood, Amino Acids cerebrospinal fluid, Child, Deficiency Diseases diet therapy, Female, Glycine therapeutic use, Humans, Ichthyosis etiology, Male, Metabolism, Inborn Errors genetics, Microcephaly etiology, Serine cerebrospinal fluid, Serine therapeutic use, Spasms, Infantile etiology, Williams Syndrome metabolism, Deficiency Diseases diagnosis, Metabolism, Inborn Errors diagnosis, Serine deficiency

Abstract

Serine deficiency disorders comprise a new group of inborn errors of serine metabolism. Patients affected with these disorders present with major neurological symptoms including congenital microcephaly, seizures, psychomotor retardation or polyneuropathy. The diagnosis of serine deficiency is based on the detection of low concentrations of the amino acids serine and glycine in fasted plasma and cerebrospinal fluid (CSF). Amino acid analysis of cerebrospinal fluid is preferable over plasma analysis, because the deficiencies are more pronounced in CSF. Because of the interference of amino acids absorbed from the diet, diagnostic procedures have to be performed in the fasted state. Although the disorders are probably rare and not many cases have been reported, recognition of serine deficiency is important, given the fact that the disorders are potentially treatable. The clinical symptoms respond well to amino acid replacement therapy. So far, three serine deficiency disorders have been reported; 3-phosphoglycerate dehydrogenase deficiency, 3-phosphoserine phosphatase deficiency and a still unexplained serine deficiency disorder. In this paper, we will discuss the various serine deficiency disorders, their biochemical abnormalities and the results of amino acid replacement therapy.

Published

1999

5. Clinical heterogeneity and novel mutations in the glycerol kinase gene in three families with isolated glycerol kinase deficiency.

Author

Sjarif DR, Sinke RJ, Duran M, Beemer FA, Kleijer WJ, Ploos van Amstel JK, and Poll-The BT

Subjects

Amino Acid Sequence, Child, Child, Preschool, Female, Glycerol metabolism, Glycerol Kinase deficiency, Humans, Infant, Male, Metabolism, Inborn Errors enzymology, Molecular Sequence Data, Pedigree, Genetic Heterogeneity, Glycerol Kinase genetics, Metabolism, Inborn Errors genetics, Mutation

Abstract

Isolated glycerol kinase deficiency (GKD) is an X linked recessive disorder. The clinical and biochemical picture may vary from a childhood metabolic crisis to asymptomatic adult "pseudohypertriglyceridaemia", the result of hyperglycerolaemia. We performed glycerol kinase (GK) gene analysis to study the molecular heterogeneity and genotype-phenotype correlation in eight males from three families with isolated GKD. All patients had hyperglycerolaemia and glyceroluria. Four patients from two families were essentially free of symptoms. Three patients had gastrointestinal symptoms with ketoacidosis or hypoglycaemia or both. One patient had recurrent convulsions as the only acute sign, without evidence that it was correlated with a catabolic state. Fasting tests in two symptomatic patients of family 1 showed hyperketotic states, together with a tendency to hypoglycaemia. The diagnosis was confirmed by a defective 14C-glycerol incorporation into trichloroacetic acid precipitable macromolecules in intact skin fibroblasts. Mutation screening of the GK gene was performed by amplification and direct sequencing of exons using PCR. Three novel mutations were identified: (1) a deletion starting downstream of exon 9, extending to the 3' end of the gene; (2) a nonsense mutation R413X caused by a C1351T transition; and (3) a missense mutation W503R caused by a T1651C transition. In addition, we found differences from the reported sequence: (1) exon 9 actually consists of two exons, which consequently will change the number of GK gene exons from 19 to 20 exons, and (2) nucleotide differences in exon 19. So far, no genotype-phenotype correlation can be established in these GKD families.

Published

1998

6. Peroxisome mosaicism in the livers of peroxisomal deficiency patients.

Author

Espeel M, Mandel H, Poggi F, Smeitink JA, Wanders RJ, Kerckaert I, Schutgens RB, Saudubray JM, Poll-The BT, and Roels F

Subjects

Bile Acids and Salts metabolism, Catalase analysis, Child, Child, Preschool, Fatty Acids metabolism, Fibroblasts ultrastructure, Humans, Immunoblotting, Immunohistochemistry, Male, Metabolism, Inborn Errors diagnosis, Microbodies enzymology, Microscopy, Electron, Pipecolic Acids metabolism, Liver ultrastructure, Metabolism, Inborn Errors pathology, Microbodies ultrastructure, Mosaicism

Abstract

Peroxisomal deficiency disorders, which are genetically transmitted, are assumed to be expressed in all cells, and the use of cultured skin fibroblasts for diagnosis and research is based on this assumption. We describe three patients with clinical, biochemical, and microscopic evidence of a peroxisomal disorder. However, their liver displays mosaicism, i.e., parenchymal cells with peroxisomes are adjacent to cells without peroxisomes. Ten percent (volume), 8%, and less than 1% of the parenchyma possessed peroxisomes that can be identified in immunocytochemical tests for six matrix and membrane proteins performed by light and electron microscopy. In the bulk of the parenchyma, catalase is localized in the cytoplasm, and in such cells no peroxisomes are evident by electron microscopy and immunolabeling for the 43-kd peroxisomal membrane protein (PMP) in two patients; in the third case, peroxisomal membrane ghosts are present. Immunoblots of peroxisomal beta-oxidation enzymes show a pattern similar to that from patients with a generalized peroxisomal deficiency. In contrast to the clinical and biochemical signs of peroxisomal dysfunction and hepatic histopathology, cultured fibroblasts from two patients demonstrate normal peroxisomal functions, including very-long-chain fatty acid oxidation and plasmalogen synthesis.

Published

1995

7. Peroxisomal disorders: a review.

Author

Fournier B, Smeitink JA, Dorland L, Berger R, Saudubray JM, and Poll-The BT

Subjects

Biological Transport, Enzymes deficiency, Genotype, Humans, Nervous System Diseases genetics, Phenotype, Proteins metabolism, Metabolism, Inborn Errors genetics, Metabolism, Inborn Errors therapy, Microbodies physiology, Microbodies ultrastructure

Abstract

Until recently peroxisomal disorders were considered to be extremely rare and the diagnostic procedures available for postanatal and prenatal diagnosis were not widely known. At present, 17 human disorders are linked to peroxisomal dysfunction. The clinical, biochemical and morphological peroxisome heterogeneity described in the different diseases illustrate that only combined analysis of all the different approaches will lead to a correct diagnosis and a coherent pathophysiological model to guide ongoing research. With the study of human peroxisomal disease, advances have been gained as to the function of the peroxisome in normal and pathological conditions. Genetic analysis of peroxisome biogenesis and research on peroxisomal targeting signals are now in progress. Peroxisomal disorders are usually classified according to the degree of biochemical impairment. In this paper, a tentative classification of peroxisomal disorders will be proposed, based on the degree of biochemical abnormalities combined with new data obtained on whether or not defective peroxisome assembly is involved: (1) disorders with peroxisome assembly deficiencies; (2) disorders with single enzyme deficiencies. The clinical onset and the major symptoms of the various disorders, and the recently discovered findings are discussed.

Published

1994

8. Sudden infant death associated with defective oxidative phosphorylation.

Author

Smeitink JA, Fischer JC, Ruitenbeek W, Duran M, Hofkamp M, Bentlage HA, and Poll-The BT

Subjects

Humans, Infant, Male, Liver Diseases etiology, Metabolism, Inborn Errors complications, Oxidative Phosphorylation, Sudden Infant Death

Published

1993

9. Formiminoglutamic/hydantoinpropionic aciduria in two siblings.

Author

Duran M, Dorland L, Meuleman EE, Renardel de Lavalette PA, Poll-The BT, and Berger R

Subjects

Female, Humans, Infant, Formiminoglutamic Acid urine, Hydantoins urine, Metabolism, Inborn Errors urine

Published

1993

10. Peroxisomal disorders: concentrations of metabolites in cerebrospinal fluid compared with plasma.

Author

ten Brink HJ, van den Heuvel CM, Poll-The BT, Wanders RJ, and Jakobs C

Subjects

Bile Acids and Salts blood, Bile Acids and Salts cerebrospinal fluid, Fatty Acids blood, Fatty Acids cerebrospinal fluid, Humans, Metabolism, Inborn Errors blood, Metabolism, Inborn Errors cerebrospinal fluid, Microbodies metabolism

Published

1993

11. Metabolic pigmentary retinopathies: diagnosis and therapeutic attempts.

Author

Poll-The BT, Billette de Villemeur T, Abitbol M, Dufier JL, and Saudubray JM

Subjects

Adolescent, Adult, Child, Child, Preschool, Female, Humans, Infant, Male, Metabolism, Inborn Errors diagnosis, Metabolism, Inborn Errors therapy, Retinal Degeneration diagnosis, Retinal Degeneration therapy, Metabolism, Inborn Errors complications, Pigment Epithelium of Eye, Retinal Degeneration etiology

Abstract

Retinal degeneration in children occurs in errors of lipid, peroxisomal and mitochondrial (including respiratory chain) metabolism. In this review the most frequent inborn errors of metabolism with retinal degeneration are discussed including abetalipoproteinaemia, classical Refsum disease, neuronal ceroid lipofuscinosis, hydroxydicarboxylic aciduria, Sjögren-Larsson syndrome, infantile Refsum disease, Kearns-Sayre syndrome and gyrate atrophy. These metabolic disorders must be differentiated from those with retinal degeneration but without known metabolic basis. In patients with such a disorder metabolic investigations should be considered whenever atypical manifestations are encountered.

Published

1992

12. [Clinical aspects of hereditary peroxisomal disorders].

Author

Billette de Villemeur T, Poll The BT, and Saudubray JM

Subjects

Humans, Infant, Newborn, Metabolism, Inborn Errors complications, Metabolism, Inborn Errors enzymology, Metabolism, Inborn Errors genetics, Microbodies ultrastructure, Nervous System Diseases diagnosis, Nervous System Diseases enzymology, Nervous System Diseases etiology, Nervous System Diseases genetics, Metabolism, Inborn Errors diagnosis, Microbodies enzymology

Published

1991

13. Clinical approach to inherited metabolic disorders in neonates.

Author

Saudubray JM, Narcy C, Lyonnet L, Bonnefont JP, Poll The BT, and Munnich A

Subjects

Acidosis, Lactic, Ammonia blood, Energy Metabolism, Hepatomegaly, Humans, Hypoglycemia, Infant, Newborn, Ketosis, Metabolism, Inborn Errors classification, Metabolism, Inborn Errors etiology, Metabolism, Inborn Errors physiopathology, Metabolism, Inborn Errors diagnosis

Abstract

Most inborn errors of intermediary metabolism presenting in the neonatal period fall schematically into three clinical categories: (1) those which lead to a neurological distress 'intoxication type' with a symptom-free interval, vomiting, comas, hypertonia, abnormal movements and frequent humoral disturbances (organic acidaemias, congenital urea cycle defects); (2) those which lead to a neurological distress 'energy deficiency' type. Frequent symptoms in this group include hyperlactacidaemia, severe hypotonia, cardiomyopathy, failure to thrive and malformations (congenital lactic acidaemias, fatty acid oxidation defects, peroxysomal disorders); (3) those which present evidence of liver dysfunction and hepatomegaly (glycogenesis, neoglucogenesis defects, galactosaemia, fructosaemia, tyrosinaemia type I). According to these three major clinical presentations and according to the proper use of few screening tests (blood gases, glucose, ammonia, lactic acid, electrolytes, acetest), we propose a method of diagnosis which groups these children into five schematical syndromes: type I MSUD; type II organic acidaemias; type III; congenital lactic acidosis; type IVa, urea cycle defects; type IVb, non-ketotic hyperglycinaemia, sulfite oxidase deficiency, peroxisomal disorders; type V liver dysfunctions. Once the above classification has been made, sophisticated and specific investigations can be planned (amino acid chromatography, organic acid chromatography, enzymatic studies, etc).

Published

1990