ABSTRACT
PURPOSE: Carnitine is a carrier molecule transporting long-chain fatty acids (LCFAs) into the mitochondria for fatty acid ß-oxidation. The purpose of this study is to evaluate the role of carnitine supplementation in parenteral nutrition (PN) within the pediatric population. Our goal was to determine a weight range for which empiric carnitine supplementation is justified and to determine a weight range at which a carnitine level should first be drawn to confirm a deficiency prior to supplementation. Secondarily, we tried to determine a relationship among carnitine deficiency, hypoglycemia, and hypertriglyceridemia. METHODS: This was a retrospective observational study to evaluate 2 groups of pediatric patients (weighing 0.68 kg to 60 kg) who were NPO and receiving PN. The first group of patients (n = 454) received carnitine supplementation (15 mg/kg/day) upon initiation of PN. The second group (n = 299) did not receive carnitine supplementation until they were determined to have a carnitine deficiency. RESULTS: The data indicated that 82% of the patients weighing less than 5 kg were deficient. Patients weighing more than 5 kg had serum carnitine levels within the normal range. Therefore, patients receiving PN and weighing less than 5 kg should be supplemented with carnitine. Comparison of triglyceride, glucose, and carnitine showed no statistically significant difference (P = .1936). CONCLUSION: Patients weighing more than 5 kg should have serum carnitine levels drawn within 7 days to determine whether supplementation is needed. There is no statistical correlation among carnitine deficiency, hypoglycemia, and hypertriglyceridemia.
ABSTRACT
INTRODUCTION: Current literature supports iron dextran as the only iron preparation compatible with parenteral nutrition (PN). Iron sucrose has been used for iron replacement therapy because of its lower rate of adverse events. The purpose of this study is to determine the physical and chemical stability of iron sucrose in PN. METHODS: Physical and chemical stability of iron sucrose in nonlipid PN solutions (PN 1 for neonates and PN 2 for patients weighing >20 kg) is tested over time in triplicate. Physical stability is determined by visually inspecting each PN solution for particulate matter and by filtering and analyzing each aliquot quantitatively for crystal precipitates. Chemical stability is confirmed if the iron concentrations by mass spectrometry remain within United States Pharmacopeia (USP) standards. RESULTS: Visual clarity is maintained in all PN solutions at hours 0 through 4. PN solution 1 remains clear for hours 8 through 24, whereas PN solution 2 shows an increase in particulate matter by 8 hours. All PN solutions 2 are considered visually incompatible by hour 24. Physical stability of iron sucrose for PN solutions 1 and 2 from hours 0 to 4 is within the USP guidelines for crystalline particulate matter. At hour 24, only solution 1 remains within USP guidelines. Chemical stability data indicate that iron concentrations are maintained throughout the 24-hour time period. CONCLUSION: The physical stability of iron sucrose in PN is time and concentration dependent. Concentrations >0.25 mg/dL showed increasing particulate and should not be added to PN. However, iron sucrose is chemically stable in PN solutions.
