carnitine and Inborn Errors of Metabolism studies

Research Excerpts

Excerpt	Relevance	Reference
"Could 10-20% of autism be prevented? We hypothesize that nonsyndromic or "essential" autism involves extreme male bias in infants who are genetically normal, but they develop deficiency of carnitine and perhaps other nutrients in the brain causing autism that may be amenable to early reversal and prevention."	8.95	Brain carnitine deficiency causes nonsyndromic autism with an extreme male bias: A hypothesis. ( Beaudet, AL, 2017)
"To assess the effectiveness and safety of carnitine supplementation in the treatment of inborn errors of metabolism."	8.88	Carnitine supplementation for inborn errors of metabolism. ( Fedorowicz, Z; Javaheri, H; Nasser, M; Noorani, Z, 2012)
"To assess the effectiveness and safety of carnitine supplementation in the treatment of inborn errors of metabolism."	8.85	Carnitine supplementation for inborn errors of metabolism. ( Fedorowicz, Z; Javaheri, H; Nasser, M; Noorani, Z, 2009)
"Combined methylmalonic aciduria and homocystinuria, cobalamin C (cblC) type, is an inherited disorder of vitamin B(12) metabolism caused by mutations in MMACHC."	7.76	Newborn screening and early biochemical follow-up in combined methylmalonic aciduria and homocystinuria, cblC type, and utility of methionine as a secondary screening analyte. ( Caggana, M; Cohen-Pfeffer, JL; Diaz, GA; Kirmse, BM; McGuire, PJ; Morrissey, MA; Salveson, BR; Sunny, S; Wasserstein, MP; Weisfeld-Adams, JD; Yu, C, 2010)
"Close observation of plasma amino acid, carnitine, and acylcarnitine profiles was performed in a patient with IVA that completed uneventful pregnancy."	7.76	Maternal isovaleric acidemia: observation of distinctive changes in plasma amino acids and carnitine profiles during pregnancy. ( Castelnovi, C; Moseley, K; Yano, S, 2010)
" Patients with the cobalamin C (CblC) defect have combined methylmalonic aciduria and homocystinuria."	7.74	Marfanoid features in a child with combined methylmalonic aciduria and homocystinuria (CblC type). ( Blom, HJ; Heil, SG; Hogeveen, M; Kluijtmans, LA; Morava, E; van de Berg, GB; van Dijken, PJ, 2007)
"A patient with pericardial effusion and a complicated presentation of primary systemic carnitine deficiency (PSCD) is described."	7.73	Pericardial effusion in primary systemic carnitine deficiency. ( Charoenpipop, D; Khowsathit, P; Kim, SZ; Levy, HL; Shih, VE; Suthutvoravut, U; Visudtibhan, A; Wattanasirichaigoon, D, 2006)
"We report on a favourable pregnancy in a woman affected by mut- methylmalonic acidaemia."	7.71	Successful pregnancy in a woman with mut- methylmalonic acidaemia. ( Baiocco, F; Boenzi, S; Deodato, F; Dionisi-Vici, C; Rizzo, C; Sabetta, G, 2002)
"Endocardial fibroelastosis (EFE) has previously been shown to be associated with tissue carnitine deficiency, although the basis for the carnitine deficiency has not been documented."	7.69	Endocardial fibroelastosis and primary carnitine deficiency due to a defect in the plasma membrane carnitine transporter. ( Bennett, MJ; Hale, DE; Pollitt, RJ; Stanley, CA; Variend, S, 1996)
"Fraternal twins who had fasting hypoglycemia, hypoketonemia, muscle weakness, and hepatic dysfunction are reported."	5.27	Hypoglycemia, hepatic dysfunction, muscle weakness, cardiomyopathy, free carnitine deficiency and long-chain acylcarnitine excess responsive to medium chain triglyceride diet. ( Bier, DM; Brown, BI; Dickie, M; Engel, AG; Glasgow, AM; Perry, LW; Todaro, J; Utter, MF, 1983)
"Could 10-20% of autism be prevented? We hypothesize that nonsyndromic or "essential" autism involves extreme male bias in infants who are genetically normal, but they develop deficiency of carnitine and perhaps other nutrients in the brain causing autism that may be amenable to early reversal and prevention."	4.95	Brain carnitine deficiency causes nonsyndromic autism with an extreme male bias: A hypothesis. ( Beaudet, AL, 2017)
"To assess the effectiveness and safety of carnitine supplementation in the treatment of inborn errors of metabolism."	4.88	Carnitine supplementation for inborn errors of metabolism. ( Fedorowicz, Z; Javaheri, H; Nasser, M; Noorani, Z, 2012)
"To assess the effectiveness and safety of carnitine supplementation in the treatment of inborn errors of metabolism."	4.85	Carnitine supplementation for inborn errors of metabolism. ( Fedorowicz, Z; Javaheri, H; Nasser, M; Noorani, Z, 2009)
"Carnitine deficiency is a secondary complication of many inborn errors of metabolism."	4.82	Treatment of carnitine deficiency. ( Winter, SC, 2003)
"When patients suffer from hepato-encephalopathy, (cardio)myopathy, dystrophy, hypoglycaemia, some metabolic diseases and several other disease states, carnitine deficiency should be considered."	4.78	[Pathogenesis and pathophysiology of carnitine deficiency, a predictable risk]. ( Przyrembel, H; Rodrigues Pereira, R; Scholte, HR, 1990)
"Macrosomia is an interfering factor for the analytes C3 and C18:1, leading to higher risk of false-positive results for methylmalonic/propionic acidemia and carnitine palmitoyl transferase type 2 deficiency, respectively."	3.96	Neonatal Macrosomia is an Interfering Factor for Analytes on the Colorado State Newborn Screen. ( Baker, PR; Wright, EL, 2020)
"Certain inborn errors of metabolism result from deficiencies in biotin containing enzymes."	3.81	Biotin deprivation impairs mitochondrial structure and function and has implications for inherited metabolic disorders. ( Corella, JA; Díaz-Ruiz, R; Hernández-Vázquez, Ade J; Ibarra-González, I; Ochoa-Ruiz, E; Ortega-Cuéllar, D; Ortiz-Plata, A; Rembao, D; Uribe-Carvajal, S; Velázquez-Arellano, A; Viollet, B, 2015)
"Infants often develop hypocarnitinemia and resultant hypoglycemia during long-term treatment with antibiotics that contain pivalic acid, but it is unknown whether maternal treatment with such agents during pregnancy induces hypocarnitinemia in fetuses or neonates."	3.80	Newborn hypocarnitinemia due to long-term transplacental pivalic acid passage. ( Kubota, M; Nasu, T; Suzuki, M; Uetake, K, 2014)
"Screening for inborn errors of metabolism using mass spectrometry is part of nationwide newborn screening programs and involves the detection of disease relevant (acyl-)carnitines and organic acids from dried blood spots."	3.79	Matrix-assisted laser desorption/ionization for simultaneous quantitation of (acyl-)carnitines and organic acids in dried blood spots. ( Dieplinger, R; Kasper, DC; Lutsch, NM; Mechtler, TP; Metz, TF; Ostermann, KM; Strupat, K, 2013)
"Urinary organic acids, plasma amino acids and acylcarnitine profile analyses are the main tools used to diagnose inborn errors of metabolisms (IEMs)."	3.78	Quantification of acylglycines in human urine by HPLC electrospray ionization-tandem mass spectrometry and the establishment of pediatric reference interval in local Chinese. ( Fong, BM; Leung, KS; Tam, S, 2012)
"Close observation of plasma amino acid, carnitine, and acylcarnitine profiles was performed in a patient with IVA that completed uneventful pregnancy."	3.76	Maternal isovaleric acidemia: observation of distinctive changes in plasma amino acids and carnitine profiles during pregnancy. ( Castelnovi, C; Moseley, K; Yano, S, 2010)
"Combined methylmalonic aciduria and homocystinuria, cobalamin C (cblC) type, is an inherited disorder of vitamin B(12) metabolism caused by mutations in MMACHC."	3.76	Newborn screening and early biochemical follow-up in combined methylmalonic aciduria and homocystinuria, cblC type, and utility of methionine as a secondary screening analyte. ( Caggana, M; Cohen-Pfeffer, JL; Diaz, GA; Kirmse, BM; McGuire, PJ; Morrissey, MA; Salveson, BR; Sunny, S; Wasserstein, MP; Weisfeld-Adams, JD; Yu, C, 2010)
" They may be suitable for the retrospective diagnosis of inborn errors of metabolism, but no data are currently available on the long-term stability of amino acids and acylcarnitine species."	3.74	Long-term stability of amino acids and acylcarnitines in dried blood spots. ( Bodamer, OA; Heinze, G; Holub, M; Lebl, J; Mascher, H; Mühl, A; Ratschmann, R; Stöckler-Ipsiroglu, S; Strnadová, KA; Votava, F; Waldhauser, F, 2007)
" Patients with the cobalamin C (CblC) defect have combined methylmalonic aciduria and homocystinuria."	3.74	Marfanoid features in a child with combined methylmalonic aciduria and homocystinuria (CblC type). ( Blom, HJ; Heil, SG; Hogeveen, M; Kluijtmans, LA; Morava, E; van de Berg, GB; van Dijken, PJ, 2007)
"A patient with pericardial effusion and a complicated presentation of primary systemic carnitine deficiency (PSCD) is described."	3.73	Pericardial effusion in primary systemic carnitine deficiency. ( Charoenpipop, D; Khowsathit, P; Kim, SZ; Levy, HL; Shih, VE; Suthutvoravut, U; Visudtibhan, A; Wattanasirichaigoon, D, 2006)
" Seven inborn errors of metabolism-- phenylketonuria (PKU), glutaric acidemia type I (GA-I), 3-methylcrotonylglycinemia deficiency (3-MCCD), methylmalonic acidemia (MMA), propionic acidemia (PA), medium-chain acylCoAdehydrogenase deficiency (MCADD), and 3-OH long-chain acyl CoA dehydrogenase deficiency (LCHADD)-were investigated."	3.73	Biomarker discovery, disease classification, and similarity query processing on high-throughput MS/MS data of inborn errors of metabolism. ( Baumgartner, C; Baumgartner, D, 2006)
"Since the addition of tandem mass spectrometry (MS/MS) to the North Carolina Newborn Screening Program, 20 infants with two consecutive elevated 3-hydroxyisovalerylcarnitine (C5OH) levels have been evaluated for evidence of inborn errors of metabolism associated with this metabolite."	3.72	Evaluation of 3-methylcrotonyl-CoA carboxylase deficiency detected by tandem mass spectrometry newborn screening. ( Boney, A; Chaing, S; Frazier, DM; Kishnani, PS; Koeberl, DD; McCandless, SE; McDonald, MT; Millington, DS; Moore, E; Muenzer, J; Smith, WE; Weavil, SD, 2003)
"We report on a favourable pregnancy in a woman affected by mut- methylmalonic acidaemia."	3.71	Successful pregnancy in a woman with mut- methylmalonic acidaemia. ( Baiocco, F; Boenzi, S; Deodato, F; Dionisi-Vici, C; Rizzo, C; Sabetta, G, 2002)
"Measurement of free carnitine and acylcarnitines allows the detection of several inborn errors of metabolism in neonatal screening."	3.71	Acylcarnitine profiles of preterm infants over the first four weeks of life. ( Hoffmann, GF; Kohlmueller, D; Linderkamp, O; Mayatepek, E; Meyburg, J; Pöschl, J; Schulze, A, 2002)
"Tandem mass spectrometric analysis of acylcarnitines and amino acids has been applied in newborn screening programmes for the detection of several inborn errors of metabolism."	3.70	Diagnosis of isovaleric acidaemia by tandem mass spectrometry: false positive result due to pivaloylcarnitine in a newborn screening programme. ( Abdenur, JE; Chamoles, NA; Fuertes, AN; Guinle, AE; Schenone, AB, 1998)
" Treatment with medium chain triglycerides and L-carnitine in the diet improved his hepatomegaly and cardiomegaly."	3.70	Milder childhood form of very long-chain acyl-CoA dehydrogenase deficiency in a 6-year-old Japanese boy. ( Abo, W; Doi, T; Fukao, T; Hayashi, K; Hori, T; Nakada, T; Takahashi, Y; Tateno, M; Terada, N, 2000)
"Endocardial fibroelastosis (EFE) has previously been shown to be associated with tissue carnitine deficiency, although the basis for the carnitine deficiency has not been documented."	3.69	Endocardial fibroelastosis and primary carnitine deficiency due to a defect in the plasma membrane carnitine transporter. ( Bennett, MJ; Hale, DE; Pollitt, RJ; Stanley, CA; Variend, S, 1996)
"Metabolic profiling of amino acids and acylcarnitines from blood spots by automated electrospray tandem mass spectrometry (ESI-MS/MS) is a powerful diagnostic tool for inborn errors of metabolism."	3.69	Screening blood spots for inborn errors of metabolism by electrospray tandem mass spectrometry with a microplate batch process and a computer algorithm for automated flagging of abnormal profiles. ( Alamoudi, M; Alwattar, M; Awad, A; Bucknall, MP; Jacob, M; Little, D; Ozand, PT; Rashed, MS, 1997)
"L-carnitine treatment prevented this fall in plasma carnitine and resulted in greater increases in excretion of acylcarnitines."	2.71	L-carnitine and exercise tolerance in medium-chain acyl-coenzyme A dehydrogenase (MCAD) deficiency: a pilot study. ( Chalmers, RA; Harrison, EL; Jones, MG; Jones, S; Lee, PJ; Leonard, JV, 2005)
"Today, carnitine treatment of inborn errors of metabolism is a safe and integral part of many treatment protocols, and a growing interest in carnitine has resulted in greater recognition of many causes of carnitine depletion."	2.53	Historical Perspective on Clinical Trials of Carnitine in Children and Adults. ( Buist, NR, 2016)
"Many inborn errors of metabolism (IEMs) may present as sudden infant death (SID)."	2.53	Inborn Errors of Metabolism That Cause Sudden Infant Death: A Systematic Review with Implications for Population Neonatal Screening Programmes. ( Bekhof, J; de Koning, TJ; Derks, TG; Heiner Fokkema, MR; Koolhaas, GD; Schielen, PC; van Rijt, WJ; van Spronsen, FJ; Visser, G, 2016)
"Many genetic diseases, especially the inborn errors of metabolism, have very low incidences, so developing a newborn screening test for each disease is not practical."	2.50	Application of mass spectrometry in newborn screening: about both small molecular diseases and lysosomal storage diseases. ( Chiang, SC; Chien, YH; Hsu, LW; Hwu, WL; Lee, NC; Wang, SF, 2014)
"This disorder, known as phenylketonuria, produces profound mental retardation if not detected and treated early in life."	2.43	A biochemical perspective on the use of tandem mass spectrometry for newborn screening and clinical testing. ( Chace, DH; Kalas, TA, 2005)
"Carnitine functions as a substrate for a family of enzymes, carnitine acyltransferases, involved in acyl-coenzyme A metabolism and as a carrier for long-chain fatty acids into mitochondria."	2.40	Genetic disorders of carnitine metabolism and their nutritional management. ( Hoppel, C; Kerner, J, 1998)
"Carnitine plays an essential role in the transfer of long-chain fatty acids across the inner mitochondrial membrane, in the detoxification of acyl moieties, and in maintaining normal levels of free coenzyme A."	2.40	Primary and secondary alterations of neonatal carnitine metabolism. ( Longo, N; Scaglia, F, 1999)
"Malonic aciduria is an extremely rare inborn error of metabolism due to malonyl-CoA decarboxylase deficiency."	1.62	Heterogenous Clinical Landscape in a Consanguineous Malonic Aciduria Family. ( Abily-Donval, L; Bekri, S; Goldenberg, A; Marret, S; Salomons, GS; Snanoudj, S; Sudrié-Arnaud, B; Tebani, A; Torre, S, 2021)
"Background Individual inborn errors of metabolism (IEMs) are rare disorders."	1.56	Inborn errors of metabolism detectable by tandem mass spectrometry in Beijing. ( Gong, LF; Kong, YY; Liu, W; Ma, ZJ; Wan, ZH; Yang, HH; Yang, N; Zhao, JQ, 2020)
"Acylcarnitine profile (ACP) is a useful tool in the biochemical diagnosis and monitoring of many acquired and inherited metabolic disorders."	1.40	Disorders associated with abnormal acylcarnitine profile among high risk Egyptian children. ( El-Mesellamy, H; Fateen, E; Gouda, AS; Zaki, SS, 2014)
"Acylcarnitines were separated on a reverse phase column and detected with triple quadrupole linear ion trap mass spectrometry."	1.39	Separation and identification of underivatized plasma acylcarnitine isomers using liquid chromatography-tandem mass spectrometry for the differential diagnosis of organic acidemias and fatty acid oxidation defects. ( Cai, Y; Fang, X; Huang, Y; Liang, C; Lin, R; Liu, L; Peng, M, 2013)
"Expanded newborn screening of inborn errors of metabolism (IEM) based on tandem mass spectrometry technology has emerged as one of the most successful preventative healthcare initiatives for presymptomatic diagnosis and treatment of rare yet treatable genetic diseases."	1.39	Expanded newborn screening of inborn errors of metabolism by capillary electrophoresis-electrospray ionization-mass spectrometry (CE-ESI-MS). ( Britz-McKibbin, P, 2013)
"Data of classical inborn errors of metabolism (IEM) of amino acids, organic acids and fatty acid oxidation are largely lacking in Hong Kong, where mass spectrometry-based expanded newborn screening for IEM has not been initiated."	1.37	Analysis of inborn errors of metabolism: disease spectrum for expanded newborn screening in Hong Kong. ( Chan, AO; Chan, AY; Chen, SP; Ching, CK; Lai, CK; Lam, CW; Law, CY; Lee, HC; Mak, CM; Shek, CC; Siu, TS; Siu, WK; Tai, HL; Tam, S; Yuen, YP, 2011)
"Acylcarnitine profile was performed in five patients using tandem mass spectrometry."	1.37	Genotype-phenotype correlations in a large series of patients with muscle type CPT II deficiency. ( Angelini, C; Anichini, A; Bruno, C; Cassandrini, D; Fanin, M; Fiorillo, C; Vianey-Saban, C, 2011)
" Information on therapeutic usage, administration, and dosage was also recorded."	1.36	Setting up an emergency stock for metabolic diseases. ( Fernandez-Llamazares, CM; Manrique-Rodríguez, S; Sanjurjo-Sáez, M; Serrano, ML, 2010)
"Four carnitine cycle defects have been described."	1.35	Disorders of the carnitine cycle and detection by newborn screening. ( Wilcken, B, 2008)
"Propionic acidemia is a hereditary metabolic disease caused by a deficiency of enzyme propionyl-CoA carboxylase, which is involved in the catabolism of ramified amino acids, odd-chain fatty acids, and other metabolites; the deficiency of this enzyme leads to an accumulation of toxic substances in the body."	1.34	Subacute presentation of propionic acidemia. ( de la Sierra García-Valdecasas, M; del Portal, LR; Delgado, C; Jiménez, LM; Macías, C; Pérez, M, 2007)
"In total, 29 cases of inborn errors of metabolism were detected."	1.33	Tandem mass neonatal screening in Taiwan--report from one center. ( Chien, YH; Chu, KL; Huang, HP; Hwu, WL; Wang, SF; Wei, ML; Wu, ST, 2006)
"In 106 newborns, confirmed inborn errors of metabolism were found."	1.32	Expanded newborn screening for inborn errors of metabolism by electrospray ionization-tandem mass spectrometry: results, outcome, and implications. ( Hoffmann, GF; Kohlmüller, D; Lindner, M; Mayatepek, E; Olgemöller, K; Schulze, A, 2003)
"Predominant clinical features include microcephaly, hydrocephalus, seizures, and white-matter changes on magnetic resonance imaging in early-onset cases."	1.31	Practical management of combined methylmalonicaciduria and homocystinuria. ( Bodamer, OA; Smith, DL, 2002)
"We have prospectively detected 163 inborn errors of metabolism."	1.30	Automated tandem mass spectrometry for mass newborn screening for disorders in fatty acid, organic acid, and amino acid metabolism. ( Chace, DH; Naylor, EW, 1999)
"This allows detection of more than 30 inborn errors of metabolism of amino acids, fatty acids, and other organic acids."	1.30	Design of a pilot study to evaluate tandem mass spectrometry for neonatal screening. ( Brandt, NJ; Christensen, E; Jensen, UG; Nørgaard-Pedersen, B; Simonsen, H; Skovby, F, 1999)
"Hypocarnitinemia was a common finding."	1.29	Variable clinical and biochemical presentation of seven Spanish cases with glutaryl-CoA-dehydrogenase deficiency. ( Aparicio, M; Font, LM; Garcia, MJ; Garzo, C; Lorenzo, G; Martinez Pardo, M; Martinez-Bermejo, A; Merinero, B; Pascual Castroviejo, I; Pérez-Cerdá, C, 1995)
"Creatine excretion was measured in two patients with methylmalonic aciduria and two patients with 3-hydroxy-3-methylglutaric aciduria."	1.28	Creatine metabolism during metabolic perturbations in patients with organic acidurias. ( Chalmers, RA; Davies, SE; Iles, RA; Stacey, TE, 1990)
"In patients diagnosed as Reye syndrome, tissue carnitine deficiency was not always recognized and no decrease in the free/total carnitine ratio was found in the liver or muscle."	1.28	Carnitine deficiency in inherited organic acid disorders and Reye syndrome. ( Kidouchi, K; Kobayashi, M; Sugiyama, N; Wada, Y, 1990)
"Carnitine metabolism was studied in a 7-y-old boy with propionic acidemia due to an almost total deficiency of propionyl-CoA carboxylase."	1.28	Metabolic studies of carnitine in a child with propionic acidemia. ( Goldblatt, PJ; Gunning, WT; Hoppel, CL; Kurczynski, TW, 1989)
"Treatment with carnitine, started during the third period of artificial ventilation, led to some improvement of muscle strength, but he still could not breathe without support."	1.27	Glutaric aciduria type II: treatment with riboflavine, carnitine and insulin. ( Blom, W; Giesberts, MA; Mooy, PD; Przyrembel, H; Scholte, HR; van Gelderen, HH, 1984)
"Mitochondrial myopathies are a clinical condition characterized by muscle weakness and fatigue in which the primary defect is localized at the level of the mitochondria."	1.27	Mitochondrial myopathies: disorders of the respiratory chain and oxidative phosphorylation. ( Byrne, E; Clark, JB; Hayes, DJ; Morgan-Hughes, JA, 1984)
"Thus, this disease is revealed by a coma due to hypoglycemia in a young child; the presence of dicarboxylic aciduria in such a situation is the main evidence for this diagnosis."	1.27	[Medium chain acyl-CoA dehydrogenase deficiency. Apropos of a case with demonstration of this enzyme deficiency]. ( Blanc, JF; Collet, JP; David, M; Divry, P; Guibaud, P; Hermier, M; Macabeo, V; Vibert, J, 1984)
"Fraternal twins who had fasting hypoglycemia, hypoketonemia, muscle weakness, and hepatic dysfunction are reported."	1.27	Hypoglycemia, hepatic dysfunction, muscle weakness, cardiomyopathy, free carnitine deficiency and long-chain acylcarnitine excess responsive to medium chain triglyceride diet. ( Bier, DM; Brown, BI; Dickie, M; Engel, AG; Glasgow, AM; Perry, LW; Todaro, J; Utter, MF, 1983)

Research

Studies (245)

Authors

Clinical Trials (5)

Trial Overview

Trial Outcomes

Anthropometric Measures of Nutritional Status (Body Mass Index [BMI] Z-scores, Weight for Length Ratios, Lean/Fat Mass Via DEXA, Growth Parameters, and Triceps Skinfold Measures)

Max CMAP Amplitude (Mean)

Timeframe	Studies, this research(%)	All Research%
pre-1990	38 (15.51)	18.7374
1990's	59 (24.08)	18.2507
2000's	78 (31.84)	29.6817
2010's	58 (23.67)	24.3611
2020's	12 (4.90)	2.80

Authors	Studies
Rücklová, K	1
Hrubá, E	1
Pavlíková, M	1
Hanák, P	1
Farolfi, M	1
Chrastina, P	1
Vlášková, H	1
Kousal, B	1
Smolka, V	1
Foltenová, H	1
Adam, T	1
Friedecký, D	1
Ješina, P	1
Zeman, J	1
Kožich, V	1
Honzík, T	1
Ziats, CA	1
Burns, WB	1
Tedder, ML	1
Pollard, L	1
Wood, T	1
Champaigne, NL	1
Snanoudj, S	2
Torre, S	1
Sudrié-Arnaud, B	2
Abily-Donval, L	1
Goldenberg, A	1
Salomons, GS	2
Marret, S	1
Bekri, S	1
Tebani, A	2
Maier, EM	1
Mütze, U	1
Janzen, N	1
Steuerwald, U	1
Nennstiel, U	1
Odenwald, B	1
Schuhmann, E	1
Lotz-Havla, AS	1
Weiss, KJ	1
Hammersen, J	1
Weigel, C	1
Thimm, E	1
Grünert, SC	2
Hennermann, JB	1
Freisinger, P	1
Krämer, J	1
Das, AM	1
Illsinger, S	1
Gramer, G	1
Fang-Hoffmann, J	1
Garbade, SF	1
Okun, JG	2
Hoffmann, GF	8
Kölker, S	3
Röschinger, W	2
Almannai, M	1
Alfadhel, M	1
El-Hattab, AW	2
Tan, J	1
Chen, D	1
Huang, J	1
Chang, R	1
Yan, T	1
Cai, R	1
Wright, EL	1
Baker, PR	1
Joshi, PR	1
Zierz, S	2
Yang, N	1
Gong, LF	1
Zhao, JQ	1
Yang, HH	1
Ma, ZJ	1
Liu, W	1
Wan, ZH	1
Kong, YY	1
Wang, S	1
Leng, J	1
Diao, C	1
Wang, Y	2
Zheng, R	1
Nowoczyn, M	1
Acquaviva-Bourdain, C	2
Corne, C	1
Minet-Quinard, R	1
Van Noolen, L	1
Garnotel, R	1
Dessein, AF	1
Imbard, A	1
Dabaj, I	1
Meinhardt, B	1
Motlagh Scholle, L	1
Seifert, F	1
Anwand, M	1
Pietzsch, M	1
Stenlid, R	1
Olsson, D	1
Cen, J	1
Manell, H	1
Haglind, C	1
Chowdhury, AI	1
Bergsten, P	1
Nordenström, A	1
Halldin, M	1
Aldubayan, SH	1
Rodan, LH	1
Berry, GT	1
Levy, HL	2
Beaudet, AL	2
Céspedes, N	1
Valencia, A	1
Echeverry, CA	1
Arce-Plata, MI	1
Colón, C	1
Castiñeiras, DE	1
Hurtado, PM	1
Cocho, JA	1
Herrera, S	1
Arévalo-Herrera, M	1
El-Gharbawy, A	1
Vockley, J	4
Knottnerus, SJG	1
Bleeker, JC	1
Wüst, RCI	1
Ferdinandusse, S	1
IJlst, L	2
Wijburg, FA	2
Wanders, RJA	1
Visser, G	3
Houtkooper, RH	1
Janeiro, P	1
Jotta, R	1
Ramos, R	1
Florindo, C	1
Ventura, FV	1
Vilarinho, L	3
Tavares de Almeida, I	1
Gaspar, A	1
Sarker, SK	1
Islam, MT	1
Biswas, A	1
Bhuyan, GS	1
Sultana, R	1
Sultana, N	1
Rakhshanda, S	1
Begum, MN	1
Rahat, A	1
Yeasmin, S	1
Khanam, M	1
Saha, AK	1
Noor, FA	1
Sajib, AA	1
Islam, ABMMK	1
Qadri, SK	1
Shahidullah, M	1
Mannan, MA	1
Muraduzzaman, AKM	1
Shirin, T	1
Rahman, SM	1
Qadri, SS	1
Saha, N	1
Akhteruzzaman, S	1
Qadri, F	1
Mannoor, K	1
Tucci, S	1
Behringer, S	1
Sturm, M	1
Spiekerkoetter, U	3
Mandour, I	1
El Gayar, D	1
Amin, M	1
Farid, TM	1
Ali, AA	1
Ostermann, KM	1
Dieplinger, R	1
Lutsch, NM	1
Strupat, K	1
Metz, TF	1
Mechtler, TP	1
Kasper, DC	1
Peng, M	1
Fang, X	1
Huang, Y	1
Cai, Y	1
Liang, C	1
Lin, R	1
Liu, L	1
Yasuno, T	2
Osafune, K	1
Sakurai, H	1
Asaka, I	1
Tanaka, A	1
Yamaguchi, S	5
Yamada, K	1
Hitomi, H	1
Arai, S	1
Kurose, Y	1
Higaki, Y	1
Sudo, M	1
Ando, S	1
Nakashima, H	1
Saito, T	1
Kaneoka, H	2
Ryckman, KK	1
Smith, CJ	1
Jelliffe-Pawlowski, LL	1
Momany, AM	1
Berberich, SL	1
Murray, JC	1
El-Mesellamy, H	1
Gouda, AS	1
Fateen, E	1
Zaki, SS	1
Nasu, T	1
Suzuki, M	1
Uetake, K	1
Kubota, M	1
Teodoro-Morrison, T	1
Kyriakopoulou, L	1
Chen, YK	1
Raizman, JE	1
Bevilacqua, V	1
Chan, MK	1
Wan, B	1
Yazdanpanah, M	1
Schulze, A	4
Adeli, K	1
Han, L	1
Wu, S	1
Ye, J	2
Qiu, W	1
Zhang, H	1
Gao, X	1
Gong, Z	1
Jin, J	1
Gu, X	1
Kiykim, E	1
Zeybek, CA	1
Zubarioglu, T	1
Cansever, S	1
Yalcinkaya, C	1
Soyucen, E	1
Aydin, A	1
Mamedov, I	1
Zolkina, I	1
Nikolaeva, E	1
Glagovsky, P	1
Sukhorukov, V	1
Ochoa-Ruiz, E	1
Díaz-Ruiz, R	1
Hernández-Vázquez, Ade J	1
Ibarra-González, I	1
Ortiz-Plata, A	1
Rembao, D	1
Ortega-Cuéllar, D	1
Viollet, B	1
Uribe-Carvajal, S	1
Corella, JA	1
Velázquez-Arellano, A	1
McCoin, CS	1
Piccolo, BD	1
Knotts, TA	1
Matern, D	4
Gillingham, MB	1
Adams, SH	1
van Rijt, WJ	1
Koolhaas, GD	1
Bekhof, J	1
Heiner Fokkema, MR	1
de Koning, TJ	1
Schielen, PC	1
van Spronsen, FJ	1
Derks, TG	1
Angelini, C	3
Nascimbeni, AC	1
Cenacchi, G	1
Tasca, E	1
Longo, N	4
Winter, S	2
Buist, NR	2
Armenian, SH	1
Lopaschuk, G	1
Wasilewska, A	1
Chalcraft, KR	1
Britz-McKibbin, P	2
Komlósi, K	1
Magyari, L	1
Talián, GC	1
Nemes, E	1
Káposzta, R	1
Mogyorósy, G	1
Méhes, K	1
Melegh, B	1
Fingerhut, R	2
Ensenauer, R	1
Arnecke, R	1
Olgemöller, B	1
Roscher, AA	1
Laforêt, P	1
Rigal, O	2
Brivet, M	5
Penisson-Besnier, I	1
Chabrol, B	2
Chaigne, D	1
Boespflug-Tanguy, O	1
Laroche, C	1
Bedat-Millet, AL	1
Behin, A	1
Delevaux, I	1
Lombès, A	1
Andresen, BS	4
Eymard, B	1
Vianey-Saban, C	7
Nasser, M	2
Javaheri, H	2
Fedorowicz, Z	2
Noorani, Z	2
Korematsu, S	1
Kosugi, Y	1
Kumamoto, T	1
Izumi, T	1
Chen, PW	1
Hwu, WL	4
Ho, MC	1
Lee, NC	3
Chien, YH	4
Ni, YH	1
Lee, PH	1
Weisfeld-Adams, JD	1
Morrissey, MA	1
Kirmse, BM	1
Salveson, BR	1
Wasserstein, MP	1
McGuire, PJ	1
Sunny, S	1
Cohen-Pfeffer, JL	1
Yu, C	1
Caggana, M	2
Diaz, GA	1
Wilcken, B	3
Arnold, GL	2
Saavedra-Matiz, CA	1
Galvin-Parton, PA	1
Erbe, R	1
Devincentis, E	1
Kronn, D	2
Mofidi, S	1
Wasserstein, M	1
Pellegrino, JE	1
Levy, PA	1
Adams, DJ	1
Nichols, M	1
Sempere, A	1
Arias, A	1
Farré, G	1
García-Villoria, J	1
Rodríguez-Pombo, P	1
Desviat, LR	1
Merinero, B	3
García-Cazorla, A	1
Vilaseca, MA	1
Ribes, A	2
Artuch, R	1
Campistol, J	1
Rocha, H	2
Sousa, C	1
Marcão, A	1
Fonseca, H	1
Bogas, M	1
Osório, RV	1
Shigematsu, Y	4
Hata, I	2
Tajima, G	1
Haussmann, U	1
Mueller, M	2
ter Veld, F	1
Stehn, M	1
Santer, R	2
Lukacs, Z	2
Footitt, EJ	1
Stafford, J	1
Dixon, M	1
Burch, M	1
Jakobs, C	2
Cleary, MA	1
De Jesus Silva Arevalo, G	1
Baumgartner, MR	1
Häberle, J	1
Rohrbach, M	1
Figueroa, AW	1
Fresse, EM	1
Polanco, OL	1
Torresani, T	1
Bouchireb, K	1
Teychene, AM	1
de Lonlay, P	1
Valayannopoulos, V	1
Gaudelus, J	1
Sellier, N	1
Bonnefont, JP	2
de Pontual, L	1
Santra, S	1
Hendriksz, C	2
Castelnovi, C	1
Moseley, K	1
Yano, S	1
Anichini, A	1
Fanin, M	1
Cassandrini, D	1
Fiorillo, C	1
Bruno, C	1
Sykut-Cegielska, J	1
Gradowska, W	1
Piekutowska-Abramczuk, D	1
Olsen, RK	2
Ołtarzewski, M	1
Pronicki, M	1
Pajdowska, M	1
Bogdańska, A	1
Jabłońska, E	1
Radomyska, B	1
Kuśmierska, K	1
Krajewska-Walasek, M	1
Gregersen, N	3
Pronicka, E	1
Fernandez-Llamazares, CM	1
Serrano, ML	1
Manrique-Rodríguez, S	1
Sanjurjo-Sáez, M	1
McGoey, RR	1
Marble, M	1
De, T	1
Kruthika-Vinod, TP	1
Nagaraja, D	1
Christopher, R	1
Lee, HC	1
Mak, CM	1
Lam, CW	1
Yuen, YP	1
Chan, AO	1
Shek, CC	1
Siu, TS	1
Lai, CK	1
Ching, CK	1
Siu, WK	1
Chen, SP	1
Law, CY	1
Tai, HL	1
Tam, S	2
Chan, AY	1
Sass, JO	2
Fong, BM	1
Leung, KS	1
Celestino-Soper, PB	1
Violante, S	1
Crawford, EL	1
Luo, R	1
Lionel, AC	1
Delaby, E	1
Cai, G	1
Sadikovic, B	1
Lee, K	1
Lo, C	1
Gao, K	1
Person, RE	1
Moss, TJ	1
German, JR	1
Huang, N	1
Shinawi, M	1
Treadwell-Deering, D	1
Szatmari, P	1
Roberts, W	1
Fernandez, B	1
Schroer, RJ	1
Stevenson, RE	1
Buxbaum, JD	1
Betancur, C	1
Scherer, SW	1
Sanders, SJ	1
Geschwind, DH	1
Sutcliffe, JS	1
Hurles, ME	1
Wanders, RJ	3
Shaw, CA	1
Leal, SM	1
Cook, EH	1
Goin-Kochel, RP	1
Vaz, FM	1
Marques, JS	1
Ramos, A	1
Lopes, L	1
Narayan, SB	1
Bennett, MJ	3
Sahoo, S	1
Franzson, L	1
Jonsson, JJ	1
Thiele, I	1
Gucciardi, A	1
Pirillo, P	1

Trial	Phase	Enrollment	Study Type	Start Date	Status
Triheptanoin's Effect on Fatty Acid Oxidation and Exercise Tolerance in Patients With Debrancher Deficiency, Glycogenin-1 Deficiency and Phosphofructoinase Deficiency at Rest and During Exercise. A Randomized, Double-blind, Placebo-controlled, Cross-over [NCT03642860]	Phase 2	3 participants (Actual)	Interventional	2018-08-15	Terminated (stopped due to Problems with recruitment)
In Vivo Study of Safety, Tolerability and Dosing Effect on SMN mRNA and Protein Levels of Valproic Acid in Patients With Spinal Muscular Atrophy[NCT00374075]	Phase 1	42 participants	Interventional	2003-09-30	Completed
Phase I/II Trial of Valproic Acid and Carnitine in Infants With Spinal Muscular Atrophy Type I (CARNI-VAL Type I)[NCT00661453]	Phase 1/Phase 2	40 participants (Actual)	Interventional	2008-04-30	Completed
Multi-center Phase II Trial of Valproic Acid and Carnitine in Patients With Spinal Muscular Atrophy (SMA CARNI-VAL Trial)[NCT00227266]	Phase 2	94 participants (Actual)	Interventional	2005-09-30	Completed
Correlation Between Carnitine Deficiency and Hypoglycemic Events in Type I Diabetes; Effects of Carnitine Supplementation on Hypoglycemic Events in Type I Diabetes[NCT00351234]		200 participants (Actual)	Observational	2004-10-31	Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Intervention	g (Mean)
	Lean Mass Baseline	Lean Mass 3 months	Lean Mass 6 months	Fat Mass Baseline	Fat Mass 3 months	Fat Mass 6 months
SMA Type 1	4317.15	4993.92	5133.83	3011.37	3618.25	4316.08

The maximum Compound Motor Action Potential (CMAP) is a measurement obtained through EMG testing that is associated with disease progression. In this study, we measure the maximum CMAP by stimulating one nerve in the hand and measuring the response of the muscle. This is done multiple times, the outcome used is the highest peak, or response observed. (NCT00227266)
Timeframe: 1 month prior to official enrollment, beginning of study (0 months), 6 months, 12 months (data point not available)

Max CMAP Amplitude Median

Intervention	mV (Mean)
	Baseline	6 months
Cohort 1a Sitters Placebo Then Treatment	2.28	2.32
Cohort 1b Sitters Treatment	2.93	2.37
Cohort 2 Standers and Walkers - Treatment	5.52	6.56

Max CMAP Area (Mean)

Intervention	mV (Median)
	Baseline	6 months
Cohort 1a Sitters Placebo Then Treatment	1.91	1.44
Cohort 1b Sitters Treatment	2.2	1.8
Cohort 2 Standers and Walkers - Treatment	5.3	5.85

The maximum Compound Motor Action Potential (CMAP) area is a measurement obtained through EMG testing that is associated with disease progression. In this study, we measure the maximum CMAP by stimulating one nerve in the hand and measuring the response of the muscle. This procedure is repeated multiple times. The maximum area is the response that results in the largest area under the response curve. (NCT00227266)
Timeframe: 1 month prior to official enrollment, beginning of study (0 months), 6 months, 12 months (data point not available)

Max CMAP Area (Median)

Intervention	mVms (Mean)
	Baseline	6 months
Cohort 1a Sitters Placebo Then Treatment	5.46	5.28
Cohort 1b Sitters Treatment	5.45	5.26
Cohort 2 Standers and Walkers - Treatment	14.85	16.26

Modified Hammersmith Change From Baseline to 6 Months

Intervention	mVms (Median)
	Baseline	6 months
Cohort 1a Sitters Placebo Then Treatment	3.6	3.74
Cohort 1b Sitters Treatment	4.6	3.4
Cohort 2 Standers and Walkers - Treatment	13.65	16.85

Comparison of Modified Hammersmith Change from baseline to 6 months. Scores range from 0 to 40. A higher score indicates a better outcome. This scale is used to assess gross motor abilities of non-ambulant children with SMA in multiple research trials as well as in clinical settings. (NCT00227266)
Timeframe: 0 months, 6 months

Modified Hammersmith Extend Baseline

Intervention	Score (Mean)
	Baseline visit (0 weeks)	6 Month visit (V2)	Change from Baseline
Cohort 1a Sitters Placebo Then Treatment	20.0	20.6	0.6
Cohort 1b Sitters Treatment	16.6	16.8	0.2

"Baseline Modified Hammersmith Extend testing. The baseline test is the score they receive during their screening visits. This scale ranges from 0 to 56. A higher score indicates a better outcome.~This scale is used to assess gross motor abilities of children with SMA in multiple research trials as well as in clinical settings." (NCT00227266)
Timeframe: 1 month prior to enrollment, at enrollment (0 months)

Intervention	Score (Mean)
	Modified Hammersmith Extend at S1 (-4 weeks)	Modified Hammersmith Extend at S2 (0 weeks)
Cohort 2 Experimental	47.0	48.3

Article	Year
Carnitine Inborn Errors of Metabolism. Molecules (Basel, Switzerland), 2019, Sep-06, Volume: 24, Issue:18 Topics: Aldehyde Oxidoreductases; Cardiomyopathies; Carnitine; Carnitine Acyltransferases; Carnitine O-Palmi	2019
Muscle Carnitine Palmitoyltransferase II (CPT II) Deficiency: A Conceptual Approach. Molecules (Basel, Switzerland), 2020, Apr-13, Volume: 25, Issue:8 Topics: Carnitine; Carnitine O-Palmitoyltransferase; Fatty Acids; Female; Genetic Association Studies; Human	2020
Brain carnitine deficiency causes nonsyndromic autism with an extreme male bias: A hypothesis. BioEssays : news and reviews in molecular, cellular and developmental biology, 2017, Volume: 39, Issue:8 Topics: Autistic Disorder; Blood-Brain Barrier; Brain; Cardiomyopathies; Carnitine; Female; Humans; Hyperamm	2017
Inborn Errors of Metabolism with Myopathy: Defects of Fatty Acid Oxidation and the Carnitine Shuttle System. Pediatric clinics of North America, 2018, Volume: 65, Issue:2 Topics: Carnitine; Fatty Acids; Humans; Infant; Infant, Newborn; Metabolism, Inborn Errors; Muscular Disease	2018
Disorders of mitochondrial long-chain fatty acid oxidation and the carnitine shuttle. Reviews in endocrine & metabolic disorders, 2018, Volume: 19, Issue:1 Topics: Animals; Carnitine; Fatty Acids; Humans; Metabolism, Inborn Errors; Mitochondria	2018
Inborn Errors of Metabolism That Cause Sudden Infant Death: A Systematic Review with Implications for Population Neonatal Screening Programmes. Neonatology, 2016, Volume: 109, Issue:4 Topics: Amino Acids; Autopsy; Carnitine; Humans; Infant; Infant, Newborn; Metabolism, Inborn Errors; Neonata	2016
Primary Carnitine Deficiency and Newborn Screening for Disorders of the Carnitine Cycle. Annals of nutrition & metabolism, 2016, Volume: 68 Suppl 3 Topics: Cardiomyopathies; Carnitine; Deficiency Diseases; Denmark; Dietary Supplements; Genetic Testing; Hum	2016
Historical Perspective on Clinical Trials of Carnitine in Children and Adults. Annals of nutrition & metabolism, 2016, Volume: 68 Suppl 3 Topics: Administration, Intravenous; Adult; Cardiomyopathies; Carnitine; Carnitine Acyltransferases; Child;	2016
Carnitine supplementation for inborn errors of metabolism. The Cochrane database of systematic reviews, 2009, Apr-15, Issue:2 Topics: Carnitine; Dietary Supplements; Humans; Metabolism, Inborn Errors; Vitamin B Complex	2009
How to use acylcarnitine profiles to help diagnose inborn errors of metabolism. Archives of disease in childhood. Education and practice edition, 2010, Volume: 95, Issue:5 Topics: Carnitine; Chemistry, Clinical; Child; Humans; Metabolism, Inborn Errors; Pediatrics	2010
Carnitine supplementation for inborn errors of metabolism. The Cochrane database of systematic reviews, 2012, Feb-15, Issue:2 Topics: Carnitine; Dietary Supplements; Humans; Infant; Metabolism, Inborn Errors; Vitamin B Complex	2012
Application of mass spectrometry in newborn screening: about both small molecular diseases and lysosomal storage diseases. Topics in current chemistry, 2014, Volume: 336 Topics: Amino Acids; Carnitine; Humans; Infant, Newborn; Lysosomal Storage Diseases; Metabolism, Inborn Erro	2014
Systemic primary carnitine deficiency: an overview of clinical manifestations, diagnosis, and management. Orphanet journal of rare diseases, 2012, Sep-18, Volume: 7 Topics: Adult; Carnitine; Child; Diagnosis, Differential; Genetic Counseling; Humans; Metabolism, Inborn Err	2012
Universal screening for inherited metabolic diseases in the neonate (and the fetus). The journal of maternal-fetal & neonatal medicine : the official journal of the European Association of Perinatal Medicine, the Federation of Asia and Oceania Perinatal Societies, the International Society of Perinatal Obstetricians, 2012, Volume: 25, Issue:Suppl 5 Topics: Acyl-CoA Dehydrogenase; Amino Acids; Carnitine; DNA; DNA Mutational Analysis; Female; Gestational Ag	2012
Defects of beta-oxidation including carnitine deficiency. International review of neurobiology, 2002, Volume: 53 Topics: Biological Transport; Carnitine; Carnitine O-Palmitoyltransferase; Deficiency Diseases; Humans; Meta	2002
Treatment of carnitine deficiency. Journal of inherited metabolic disease, 2003, Volume: 26, Issue:2-3 Topics: 3-Hydroxyacyl CoA Dehydrogenases; Carnitine; Humans; Metabolism, Inborn Errors	2003
Carnitine-acylcarnitine translocase deficiency: identification of a novel molecular defect in a Bedouin patient. Journal of inherited metabolic disease, 2004, Volume: 27, Issue:2 Topics: Arabs; Carnitine; Carnitine Acyltransferases; Fatal Outcome; Humans; Infant, Newborn; Israel; Male;	2004
A biochemical perspective on the use of tandem mass spectrometry for newborn screening and clinical testing. Clinical biochemistry, 2005, Volume: 38, Issue:4 Topics: Amino Acids; Carnitine; Humans; Infant, Newborn; Infant, Newborn, Diseases; Mass Spectrometry; Metab	2005
[Three congenital metabolic diseases in the Faeroe Islands. Incidence, clinical and molecular genetic characteristics of Faeroese children with glycogen storage disease type IIIA, carnitine transporter deficiency and holocarboxylase synthetase deficiency] Ugeskrift for laeger, 2006, Feb-13, Volume: 168, Issue:7 Topics: Adult; Carnitine; Child; Child, Preschool; Denmark; Female; Glycogen Storage Disease Type III; Holoc	2006
[Metabolic myopathies in childhood. A review in summarized form]. Monatsschrift Kinderheilkunde : Organ der Deutschen Gesellschaft fur Kinderheilkunde, 1984, Volume: 132, Issue:8 Topics: Carnitine; Carnitine O-Palmitoyltransferase; Child; Child, Preschool; Cytochrome-c Oxidase Deficienc	1984
Cardiac carnitine-binding protein. Nutrition reviews, 1984, Volume: 42, Issue:5 Topics: Animals; Carnitine; Carrier Proteins; Cricetinae; Heart Diseases; Metabolism, Inborn Errors; Myocard	1984
[Morphology of metabolic myopathies]. Monatsschrift Kinderheilkunde : Organ der Deutschen Gesellschaft fur Kinderheilkunde, 1984, Volume: 132, Issue:8 Topics: Carnitine; Glycogen Storage Disease Type II; Glycogen Storage Disease Type III; Glycogen Storage Dis	1984
[Hereditary metabolic muscular diseases caused by demonstrable enzyme defect]. Deutsche medizinische Wochenschrift (1946), 1980, Oct-17, Volume: 105, Issue:42 Topics: alpha-Glucosidases; AMP Deaminase; Carnitine; Carnitine O-Palmitoyltransferase; Glucan 1,4-alpha-Glu	1980
Possible carnitine requirement of the newborn and the effect of genetic disease on the carnitine requirement. Nutrition reviews, 1981, Volume: 39, Issue:11 Topics: Adipose Tissue, Brown; Animals; Carnitine; Carnitine O-Palmitoyltransferase; Female; Humans; Infant	1981
Organic acidurias and related abnormalities. Critical reviews in clinical laboratory sciences, 1995, Volume: 32, Issue:4 Topics: Acids; Carnitine; Diet; Gas Chromatography-Mass Spectrometry; Humans; Infant, Newborn; Lactates; Lac	1995
L-Carnitine. Archives of disease in childhood, 1996, Volume: 74, Issue:6 Topics: Carnitine; Child, Preschool; Humans; Infant; Metabolism, Inborn Errors	1996
[Abnormal gene expression related with symptoms in inherited metabolic disease]. Seikagaku. The Journal of Japanese Biochemical Society, 1996, Volume: 68, Issue:10 Topics: Albinism; Animals; Carnitine; Gene Deletion; Gene Expression; Hydrolases; Metabolism, Inborn Errors;	1996
Genetic disorders of carnitine metabolism and their nutritional management. Annual review of nutrition, 1998, Volume: 18 Topics: Animals; Carnitine; Diet, Fat-Restricted; Dietary Carbohydrates; Fatty Acids; Humans; Metabolism, In	1998
Primary and secondary alterations of neonatal carnitine metabolism. Seminars in perinatology, 1999, Volume: 23, Issue:2 Topics: Carnitine; Diet; Fatty Acids; Humans; Infant, Newborn; Metabolism, Inborn Errors; Oxidation-Reductio	1999
Recent developments in the investigation of inherited metabolic disorders using cultured human cells. Molecular genetics and metabolism, 1999, Volume: 68, Issue:2 Topics: 3-Hydroxyacyl CoA Dehydrogenases; Carnitine; Carnitine O-Palmitoyltransferase; Cell Line; Fatty Acid	1999
[Medium chain Acyl-Coa Dehydrogenase deficiency. A diagnostic challenge for clinicians and laboratory]. Duodecim; laaketieteellinen aikakauskirja, 1996, Volume: 112, Issue:1 Topics: Acyl-CoA Dehydrogenase; Acyl-CoA Dehydrogenases; Carnitine; Child; Child, Preschool; Female; Humans;	1996
Secondary carnitine deficiency and impaired docosahexaenoic (22:6n-3) acid synthesis: a common denominator in the pathophysiology of diseases of oxidative phosphorylation and beta-oxidation. FEBS letters, 2000, Feb-18, Volume: 468, Issue:1 Topics: Animals; Carnitine; Disease Models, Animal; Docosahexaenoic Acids; Humans; Metabolism, Inborn Errors	2000
Metabolic myopathies. The Medical clinics of North America, 1979, Volume: 63, Issue:4 Topics: alpha-Glucosidases; AMP Deaminase; Carnitine; Carnitine O-Palmitoyltransferase; Creatine Kinase; Fem	1979
Inherited disorders of mitochondrial fatty acid oxidation. Progress in liver diseases, 1992, Volume: 10 Topics: Carnitine; Electron Transport; Fatty Acids; Humans; Metabolism, Inborn Errors; Mitochondria; Oxidati	1992
Plasma and mitochondrial membrane carnitine transport defects. Progress in clinical and biological research, 1992, Volume: 375 Topics: Biological Transport; Carnitine; Carnitine Acyltransferases; Cell Membrane; Humans; Intracellular Me	1992
Approach to the patient with a fatty acid oxidation disorder. Progress in clinical and biological research, 1992, Volume: 375 Topics: Acids; Carnitine; Fatty Acids; Humans; Metabolism, Inborn Errors	1992
Clinical and biochemical aspects of carnitine deficiency and insufficiency: transport defects and inborn errors of beta-oxidation. Critical reviews in clinical laboratory sciences, 1992, Volume: 29, Issue:3-4 Topics: Biological Transport, Active; Carnitine; Fatty Acids; Humans; Metabolism, Inborn Errors; Mitochondri	1992
Chromatographic techniques in inborn errors of metabolism. Biomedical chromatography : BMC, 1991, Volume: 5, Issue:3 Topics: Acetylcarnitine; Carnitine; Chromatography, Gas; Chromatography, High Pressure Liquid; Chromatograph	1991
Carnitine homeostasis in the organic acidurias. Progress in clinical and biological research, 1990, Volume: 321 Topics: Carnitine; Homeostasis; Humans; Mass Spectrometry; Metabolism, Inborn Errors	1990
Primary carnitine deficiency. Journal of clinical chemistry and clinical biochemistry. Zeitschrift fur klinische Chemie und klinische Biochemie, 1990, Volume: 28, Issue:5 Topics: Carnitine; Child, Preschool; Female; Humans; Infant; Male; Metabolism, Inborn Errors	1990
Secondary carnitine deficiency. Journal of clinical chemistry and clinical biochemistry. Zeitschrift fur klinische Chemie und klinische Biochemie, 1990, Volume: 28, Issue:5 Topics: Adolescent; Carnitine; Child; Female; Humans; Infant; Male; Metabolism, Inborn Errors; Vitamin B Def	1990
[Pathogenesis and pathophysiology of carnitine deficiency, a predictable risk]. Tijdschrift voor kindergeneeskunde, 1990, Volume: 58, Issue:5 Topics: Adult; Cardiomyopathies; Carnitine; Child; Child, Preschool; Female; Hepatic Encephalopathy; Humans;	1990
[Mitochondrial metabolism disorders and their implications for the locomotor system and heart. I]. Arquivos brasileiros de cardiologia, 1989, Volume: 52, Issue:4 Topics: Acetyl Coenzyme A; Amino Acids; Carbohydrate Metabolism; Carnitine; Citric Acid Cycle; DNA, Mitochon	1989
Mitochondrial myopathies. Journal of inherited metabolic disease, 1987, Volume: 10 Suppl 1 Topics: Adenosine Triphosphatases; Biological Transport; Carnitine; Citric Acid Cycle; Cytochrome-c Oxidase	1987
Therapy of mitochondrial disorders. Journal of inherited metabolic disease, 1987, Volume: 10 Suppl 1 Topics: Carnitine; Electron Transport; Enzyme Precursors; Fatty Acids; Female; Humans; Male; Metabolism, Inb	1987
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986
Carnitine metabolism and function in humans. Annual review of nutrition, 1986, Volume: 6 Topics: Absorption; Acidosis; Adolescent; Adult; Aged; Animals; Biological Transport; Cardiomyopathies; Carn	1986

Article	Year
L-carnitine and exercise tolerance in medium-chain acyl-coenzyme A dehydrogenase (MCAD) deficiency: a pilot study. Journal of inherited metabolic disease, 2005, Volume: 28, Issue:2 Topics: 3-Hydroxybutyric Acid; Acids; Acyl-CoA Dehydrogenase; Adolescent; Adult; Anaerobic Threshold; Blood	2005
The role of carnitine supplementation in valproic acid therapy. Pediatrics, 1994, Volume: 93, Issue:6 Pt 1 Topics: Carnitine; Child; Double-Blind Method; Fatty Acid Desaturases; Humans; Metabolism, Inborn Errors; Va	1994
Diagnosis of inborn errors of metabolism by acylcarnitine profiling in blood using tandem mass spectrometry. Journal of inherited metabolic disease, 1997, Volume: 20, Issue:3 Topics: Carnitine; Child; Chromatography, Liquid; Fatty Acids; Female; Humans; Mass Spectrometry; Metabolism	1997
Carnitine reduces fasting ketogenesis in patients with disorders of propionate metabolism. Lancet (London, England), 1986, Feb-08, Volume: 1, Issue:8476 Topics: Carnitine; Child; Child, Preschool; Depression, Chemical; Fasting; Female; Humans; Infant; Ketone Bo	1986

carnitine and Inborn Errors of Metabolism