Carnitine deprivation adversely affects cardiac performance in the lipopolysaccharide- and hypoxia/reoxygenation-stressed piglet heart.

Sepsis and hypoxia are important stressors for the neonate. Newborn infants receiving total parenteral nutrition are routinely deprived of carnitine and develop low carnitine plasma and tissue levels. Because of its high metabolic rate and dependence on fatty acids for energy, the newborn heart may be particularly vulnerable to stress in the face of an inadequate carnitine supply. To investigate whether carnitine deprivation affects cardiac performance under stress, 23 neonatal piglets received parenteral nutrition for 2-3 weeks that was either carnitine free (CARN -) or supplemented (CARN +) with L-carnitine (400 mg/L). Bacterial endotoxin (lipopolysaccharide (LPS), 250 microg/kg intravenous bolus) or saline vehicle was administered to anesthetized piglets 3 h prior to study of isolated perfused hearts. Left ventricular systolic pressure (LVSP), left ventricular end diastolic pressure, and left ventricular developed pressure (LVDP) were measured in vitro under aerobic, hypoxic, and reoxygenation conditions in all animals. Plasma and tissue carnitine values were lower in CARN - than in CARN + piglets. In hearts from LPS-treated animals prior to hypoxia, there was no difference in ventricular compliance between CARN - and CARN + groups. LVSP and LVDP were lower in CARN - than CARN + hearts. During hypoxia, LVSP and LVDP fell, but left ventricular end diastolic pressure increased in hearts from both LPS- and saline- treated piglets. Reoxygenation led to poorer recovery in CARN - than CARN + hearts from LPS-treated animals, but not from saline controls. During hypoxia/reoxygenation, lactate efflux initially rose and then fell, while carnitine efflux increased continually. Acetyl- and medium-chain acylcarnitines were detected in the coronary effluent. Our findings suggest that carnitine deprivation diminishes heart carnitine concentrations and impairs cardiac recovery from combined endotoxic and hypoxic stress. Possible mechanisms include reduced acyl buffering and/or impaired transport of fatty acyl groups into mitochondria.

Carnitine deprivation adversely affects cardiovascular response to bacterial endotoxin (LPS) in the anesthetized neonatal pig.

Sepsis and endotoxemia are important stressors for the neonate. Newborn infants receiving total parenteral nutrition are routinely deprived of carnitine. To investigate whether carnitine deprivation affects the neonate's ability to respond to endotoxin, 19 newborn piglets received parenteral nutrition for 2-3 weeks that was either carnitine free (CARN-) or supplemented (CARN+) with L-carnitine (400 mg/L). Cardiovascular performance, i.e., heart rate; blood pressure (BP); cardiac output (CO); systemic vascular resistance (SVR), and metabolic response, i.e., plasma glucose; lactate; tumor necrosis factor alpha; tissue nitric oxide; and urinary nitrites, were studied serially in anesthetized piglets for 3 h after endotoxin (lipopolysaccharide (LPS), 250 microg/kg intravenous bolus) or vehicle administration. Plasma and tissue carnitine values were lower in CARN- than in CARN+ piglets. Prior to LPS, no differences were found for most parameters (excepting lower diastolic BP and SVR in CARN- animals). Systolic, diastolic, and mean BP fell after LPS but recovered by the end of the experiment. Nadirs were lower in CARN- than in CARN+ piglets. CO tended to be higher in CARN- than in CARN+ animals and fell after LPS. SVR fell after LPS and was lower in CARN- than in CARN+ piglets. LPS-treated animals transiently increased urinary flow. By all measures (plasma tumor necrosis factor alpha, glucose and lactate, tissue nitric oxide, and urinary nitrite excretion), LPS provocation was similar for both groups. Chronologically, BP changes were more closely related to SVR than to CO. Our findings suggest that carnitine deprivation diminishes tissue carnitine concentrations and adversely affects cardiovascular response to LPS, in part mediated by the peripheral vasculature.

Analysis of carnitine esters by radio-high performance liquid chromatography in cultured skin fibroblasts from patients with mitochondrial fatty acid oxidation disorders.

Acylcarnitines are important diagnostic markers for inborn errors of fatty acid oxidation, but their analysis in body fluids may not always be reliable. Recently, disease-specific acylcarnitine profiles generated by cultured skin fibroblasts were reported to facilitate the diagnosis by localizing a specific enzymatic defect in the mitochondrial beta-oxidation pathway. Using a novel methodologic approach, fibroblasts from 16 patients with inborn errors of fatty acid oxidation and 13 control subjects were preincubated with L-[3H]carnitine to label the intracellular carnitine pool. Cells were subsequently incubated with unlabeled palmitic acid and, after methanol extraction of cells and media, labeled free carnitine and acylcarnitines were analyzed by radio-HPLC. Quantitation was based on the integrated radioactivity of individual peaks relative to the total radioactivity recovered. In control cell lines, all saturated acylcarnitines were detected, and reference values were established. With the exception of one cell line deficient in electron transfer flavoprotein, all mutant cell lines showed abnormal and disease-specific relative concentrations of acylcarnitines. Advantages of the method include use of a small number of cells, no need for trypsinization and permeabilization of cells before incubation, simple extraction without purification of the specimen before HPLC, and relatively inexpensive equipment. The method allows a focused approach to the subsequent, more laborious confirmation of a particular disease by direct enzymatic and/or molecular analysis. It remains to be established whether the method can replace widely used global measurements of fatty acid oxidation rates in vitro that do not provide specific information about the enzyme deficiency involved.

Neonatal nutritional carnitine deficiency: a piglet model.

The clinical significance of nutritional carnitine deficiency remains controversial. To investigate this condition under controlled conditions, an animal model was developed using the parenterally alimented, carnitine-deprived newborn piglet. Forty-five piglets received total parenteral nutrition for 2-3 wk that was either carnitine-free or supplemented with 100-400 mg/L L-carnitine. Blood and a muscle biopsy were taken at the initial surgery. Carnitine balance studies were performed at 11-14 d of age. Blood, liver, heart, and skeletal muscle were taken at sacrifice for analysis of carnitine, electron microscopy, and oxidation studies. Carnitine-deprived piglets were in negative carnitine balance and had lower blood, urine, and tissue levels of carnitine than carnitine-supplemented animals. There was a positive correlation between excretion and plasma concentrations of free carnitine with an apparent renal threshold between 15 and 35 micromol/L. Plasma levels were correlated with liver and heart, but not muscle, concentrations of total acid-soluble carnitine. Carnitine-deprived piglets had evidence of lipid deposition in liver and skeletal muscle and tended to have a higher incidence of muscle weakness and cardiac failure. Basal rates of oxidation of [14C]palmitate to 14CO2 and 14C-acid-soluble products were lower in liver homogenates from carnitine-deprived piglets than in those from carnitine-supplemented animals and increased in a dose-dependent fashion with the addition of L-carnitine (0, 50, and 500 micromol/L) in vitro. In summary, carnitine deprivation in the neonatal piglet resulted in low carnitine status and morphologic/functional disturbances compatible with carnitine deficiency. The described animal model appears to be suitable for the investigation of neonatal nutritional carnitine deficiency.

Quantitation of short- and medium-chain acylcarnitines in plasma by radioisotopic exchange/high-performance liquid chromatography.

A method for the quantitation of short- and medium-chain acylcarnitines in plasma and its clinical application are described. The method is based on enzymatic exchange of L-[3H]carnitine into the acylcarnitine pool, subsequent separation of labeled acylcarnitines by high-performance liquid chromatography, and quantitation of the radioactivity by a beta flowthrough detector. Since only acylcarnitines are detected, no sample cleanup procedure is required. Isotopic equilibrium, a prerequisite for accurate quantitation, was reached in plasma after 1 h of incubation for all acylcarnitines except isovalerylcarnitine which required a longer incubation time. No significant hydrolysis of acylcarnitines occurred during the incubation. Linearity was demonstrated after adding increasing amounts of individual acylcarnitines to plasma. The method is highly sensitive requiring no L-carnitine administration to the patient and differentiates short-chain acylcarnitine isomers. It is suitable for the detection of a number of inborn errors of organic acid and fatty acid metabolism.

Latent herpes simplex virus reactivation in the guinea pig. An animal model for recurrent disease.

The purpose of this investigation was to establish an animal model by which latent herpetic disease could be mechanically reactivated, yielding an adequate number of recurrent clinical lesions in the guinea pig. To determine strain virulence, hairless guinea pigs were inoculated with three different strains of herpes simplex virus (HSV) using a spring-loaded multiple puncture apparatus. HSV-1 strains SC-16 and McKrae produced an average of 21 and 8 lesions per infected area, respectively. The HSV-2 strain (333) produced the lowest number at an average of 3 lesions per site. Following the determination of strain virulence, a larger number of guinea pigs, Hartley and hairless, were inoculated with the same HSV strains in a similar fashion as previously described. The primary infection was evident from 6 to 12 hours postinfection (PI) by the initial appearance of small pustules, which peaked by day 2, seen as dome-shaped fluid-filled sacs. These initial lesions burst, crusted (day 6 PI), and had resolved and flattened between days 9 and 12 PI. At 4-6 weeks PI the inoculated areas were stripped 6 times per area with cellophane tape. Recurrent lesions were seen in the majority of the stripped areas (89-100%). The best results were achieved with the HSV-1 (SC-16) strain in hairless guinea pigs, which peaked on day 3 poststripping, producing an average of 12.25 lesions per area. The hairless guinea pig is ideal for this type of experiment because its use eliminates the trauma associated with denudation, a procedure necessary when using haired (Hartley) animals.(ABSTRACT TRUNCATED AT 250 WORDS)