Significance of Levocarnitine Treatment in Dialysis Patients

Carnitine is a naturally occurring amino acid derivative that is involved in the transport of long-chain fatty acids to the mitochondrial matrix. There, these substrates undergo β-oxidation, producing energy. The major sources of carnitine are dietary intake, although carnitine is also endogenously synthesized in the liver and kidney. However, in patients on dialysis, serum carnitine levels progressively fall due to restricted dietary intake and deprivation of endogenous synthesis in the kidney. Furthermore, serum-free carnitine is removed by hemodialysis treatment because the molecular weight of carnitine is small (161 Da) and its protein binding rates are very low. Therefore, the dialysis procedure is a major cause of carnitine deficiency in patients undergoing hemodialysis. This deficiency may contribute to several clinical disorders in such patients. Symptoms of dialysis-related carnitine deficiency include erythropoiesis-stimulating agent-resistant anemia, myopathy, muscle weakness, and intradialytic muscle cramps and hypotension. However, levocarnitine administration might replenish the free carnitine and help to increase carnitine levels in muscle. This article reviews the previous research into levocarnitine therapy in patients on maintenance dialysis for the treatment of renal anemia, cardiac dysfunction, dyslipidemia, and muscle and dialytic symptoms, and it examines the efficacy of the therapeutic approach and related issues.     

Depletion of heart and skeletal muscle carnitine in the normal rat by peritoneal dialysis

Serum carnitine values are markedly reduced during dialysis in patients with end-stage renal disease. In an effort to obtain more evidence for dialysis induced carnitine depletion in tissue an antimal model was developed. It was found that a relatively short term peritoneal dialysis treatment in the normal rat led to a 50% decrease in serum carnitine and a 50% reduction of carnitine in the heart and skeletal muscle. The concentration of carnitine in liver did not change. The results indicate that this model may be suitable for determining specific effects of carnitine depletion in heart and skeletal muscle as well as studying the effects of dialysis under various experimental conditions.     

Levocarnitine and dialysis: a review.

Among the various metabolic abnormalities documented in dialysis patients are abnormalities related to the metabolism of fatty acids. Aberrant fatty-acid metabolism has been associated with the promotion of free-radical production, insulin resistance, and cellular apoptosis. These processes have been identified as important contributors to the morbidity experienced by dialysis patients. There is evidence that levocarnitine supplementation can modify the deleterious effects of defective fatty-acid metabolism. Patients receiving hemodialysis and, to a lesser degree, peritoneal dialysis have been shown to be carnitine deficient, as manifested by reduced levels of plasma free carnitine and an increase in the acyl:free carnitine ratio. Cardiac and skeletal muscles are particularly dependent on fatty-acid metabolism for the generation of energy. A number of clinical abnormalities have been correlated with a low plasma carnitine status in dialysis patients. Clinical trials have examined the efficacy of levocarnitine therapy in a number of conditions common in dialysis patients, including skeletal-muscle weakness and fatigue, cardiomyopathy, dialysis-related hypotension, hyperlipidemia, and anemia poorly responsive to recombinant human erythropoietin therapy (rHuEPO). This review examines the evidence for carnitine deficiency in patients requiring dialysis, and documents the results of relevant clinical trials of levocarnitine therapy in this population. Consensus recommendations by expert panels are summarized and contrasted with present guidelines for access to levocarnitine therapy by dialysis patients.     

The Role of Carnitine and Carnitine Supplementation During Exercise in Man and in Individuals with Special Needs

Carnitine is critical for normal skeletal muscle bioenergetics. Carnitine has a dual role as it is required for long-chain fatty acid oxidation, and also shuttles accumulated acyl groups out of the mitochondria. Muscle requires optimization of both of these metabolic processes during peak exercise performance. Theoretically, carnitine availability may become limiting for either fatty acid oxidation or the removal of acyl-CoAs during exercise. Despite the theoretical basis for carnitine supplementation in otherwise healthy persons to improve exercise performance, clinical data have not demonstrated consistent benefits of carnitine administration. Additionally, most of the anticipated metabolic effects of carnitine supplementation have not been observed in healthy persons. The failure to demonstrate clinical efficacy of carnitine may reflect the complex pharmacokinetics and pharmacodynamics of carnitine supplementation, the challenges of clinical trial design for performance endpoints, or the adequacy of endogenous carnitine content to meet even extreme metabolic demands in the healthy state.

In patients with end stage renal disease there is evidence of impaired cellular metabolism, the accumulation of metabolic intermediates and increased carnitine demands to support acylcarnitine production. Years of nutritional changes and dialysis therapy may also lower skeletal muscle carnitine content in these patients. Preliminary data have demonstrated beneficial effects of carnitine supplementation to improve muscle function and exercise capacity in these patients.

Peripheral arterial disease (PAD) is also associated with altered muscle metabolic function and endogenous acylcarnitine accumulation. Therapy with either carnitine or propionylcarnitine has been shown to increase claudication-limited exercise capacity in patients with PAD.

Further clinical research is needed to define the optimal use of carnitine and acylcarnitines as therapeutic modalities to improve exercise performance in disease states, and any potential benefit in healthy individuals.     

The use of carnitine in pediatric nutrition.

Carnitine is synthesized endogenously from methionine and lysine in the liver and kidney and is available exogenously from a meat and dairy diet and from human milk and most enteral formulas. Parenteral nutrition (PN) does not contain carnitine unless it is extemporaneously added. The primary role of carnitine is to transport long-chain fatty acids across the mitochondrial membrane, where they undergo beta-oxidation to produce energy. Although the majority of patients are capable of endogenous synthesis of carnitine, certain pediatric populations, specifically neonates and infants, have decreased biosynthetic capacity and are at risk of developing carnitine deficiency, particularly when receiving PN. Studies have evaluated for several decades the effects of carnitine supplementation in pediatric patients receiving nutrition support. Early studies focused primarily on the effects of supplementation on markers of fatty acid metabolism and nutrition markers, including weight gain and nitrogen balance, whereas more recent studies have evaluated neonatal morbidity. This review describes the role of carnitine in metabolic processes, its biosynthesis, and carnitine deficiency syndromes, as well as reviews the literature on carnitine supplementation in pediatric nutrition.     

A paleolithic diet is more satiating per calorie than a mediterranean-like diet in individuals with ischemic heart disease

Carnitine is a conditionally essential nutrient that plays a vital role in energy production and fatty acid metabolism. Vegetarians possess a greater bioavailability than meat eaters. Distinct deficiencies arise either from genetic mutation of carnitine transporters or in association with other disorders such as liver or kidney disease. Carnitine deficiency occurs in aberrations of carnitine regulation in disorders such as diabetes, sepsis, cardiomyopathy, malnutrition, cirrhosis, endocrine disorders and with aging. Nutritional supplementation of L-carnitine, the biologically active form of carnitine, is ameliorative for uremic patients, and can improve nerve conduction, neuropathic pain and immune function in diabetes patients while it is life-saving for patients suffering primary carnitine deficiency. Clinical application of carnitine holds much promise in a range of neural disorders such as Alzheimer's disease, hepatic encephalopathy and other painful neuropathies. Topical application in dry eye offers osmoprotection and modulates immune and inflammatory responses. Carnitine has been recognized as a nutritional supplement in cardiovascular disease and there is increasing evidence that carnitine supplementation may be beneficial in treating obesity, improving glucose intolerance and total energy expenditure.     

左旋肉毒碱的代谢与营养效应

Carnitine is a water solule quaternary ammonium compound,which isa natural constituent of higher organisms,in particular of cells of animal origin.In humans,carnitine is synthesized in liver,brain and kidney starting from protein-bound lysine and methionine.Skeletal and heart muscle cannot synthesize carnitine.Therefore,these tissues are entirely dependent on carnitine uptake from the blood.In tissues and in physiological fluids carnitine is present in a free and an esterified form.The proportion of esterified carnitine may vary considerably with nutritional conditions,exercise and disease states.Tissue carnitine content depends on many factors: dietary carnitine,lysine,methionine and co-factor intake,carnitine synthesis (in uremia carnitine synthesis in the kidney is obviously reduced or absent),carnitine transport inside and outside tissues,and carnitine excretion.The transport of long-chain fatty acid esters to sites of beta-oxidation in the mitochondrial matrix requires L-carnitine.Besides,carnitine acts as a sink and allows a shift of the acyl pressure from the mitochondria to the cytoplasm.It has been suggested that carnitine is also important for the transport of the acyl groups (metabolic energy)from one cell to another cell and into the appropriate cellular compartment.Tissue carnitine content is much higher htan tissue CoA content and so acylcarnitines may also serve as storage for metabolic energy.By modulating the tissue content of acyl-CoA compounds which inhibit many enzyme activities (e.g.pyruvate dehydrogenase activity),carnitine may regulate many metabolic pathways.Carnitine system is located in the crossroads of intermediate metabolism and carnitine deficiency and supplementation may affect lipid,glucose and protein metabolism (and eventually nutrition) not only in primary,but also in secondary carnitine deficiency.Some positive effects of carnitine supplementation have been reported in experimental studies,in newborns,in patients treated with artificial nutrition (e.g. in acutely ill patients,in which carnitine excretion may be elevated),and in several disease states.It may be difficult to identify carnitine depleted patients which could benefit from carnitine Suplementation,because serum carnitine levels may be unrelated to tissue carnitine content.Therefore,a trial of L-carnitine may be considered,when insufficient intake or increased requirements are suspected.     

Beriberi after bariatric surgery

Bariatric surgery is in general the only effective treatment for morbid obesity. Bariatric surgery is frequently associated with vitamin and mineral deficiencies which may lead to neurological and other symptoms. We describe a case of severe vitamin B1 (thiamine) deficiency. CASE DESCRIPTION: A 49-year-old man visited the emergency department with acute confusion, muscle weakness in arms and legs and visual impairment after a period of dysphagia and recurrent vomiting. Four months earlier, he had had bariatric gastric sleeve surgery for morbid obesity. Laboratory tests demonstrated that he had vitamin B1 deficiency, in view of which the diagnosis of beriberi and Wernicke encephalopathy was made. Despite normalisation of the vitamin B1 concentration following intravenous supplementation, the muscle strength hardly recovered and the patient developed Korsakov syndrome. CONCLUSION: For this deficiency there is no other treatment than vitamin B1 supplementation. Timely recognition of vitamin deficiencies and pro-active supplementation are essential in order to prevent serious complications following bariatric surgery.     

CARNITINE AND DISEASES OF SKELETAL MUSCLE

Carnitine deficiency in man whether due to the lack of the enzyme carnitine palmityl transferase (CPT) or lack of the biosynthetic enzymes for carnitine can produce muscle weakness, rhabdomyolysis and myoglobinuria. These patients respond to high carbohydrate feeding with or without added carnitine to their diets.     

Low plasma carnitine in patients on prolonged total parenteral nutrition: association with low plasma lysine

Plasma carnitine levels were determined in 17 patients maintained on long-term total parenteral nutrition (TPN) for a mean (+/- SEM) period of 69 +/- 11 months (range 12-196). All had severe malabsorption and were dependent on intravenous feeding. Plasma carnitine was determined by a modified Cederblad enzymatic method. Mean plasma carnitine was significantly below the mean normal for females (p less than 0.02) and borderline low for males (p = 0.07). In six patients the levels were below the low normal range, and in five others they were at the lowest levels of normal. Of the six patients with normal levels, three had elevated serum creatinine, indicating renal dysfunction which may by itself elevate plasma carnitine. In 10 patients the plasma levels of lysine (a carnitine precursor) were determined and found to be lower than normal (p less than 0.05). Plasma carnitine levels correlated positively with serum albumin (r = 0.62, p less than 0.05), and negatively with serum alkaline phosphatase (r = -0.64, p less than 0.05). Thus, patients maintained on long-term TPN may have low plasma carnitine, which could represent carnitine deficiency. The low plasma carnitine may be related to a deficiency of the carnitine precursor lysine. Further studies are required to determine the significance of the low plasma carnitine and whether carnitine supplementation should be required in long-term TPN.     

History of L-carnitine: implications for renal disease.

L-carnitine (LC) plays an essential metabolic role that consists in transferring the long chain fatty acids (LCFAs) through the mitochondrial barrier, thus allowing their energy-yielding oxidation. Other functions of LC are protection of membrane structures, stabilizing a physiologic coenzyme-A (CoA)-sulfate hydrate/acetyl-CoA ratio, and reduction of lactate production. On the other hand, numerous observations have stressed the carnitine ability of influencing, in several ways, the control mechanisms of the vital cell cycle. Much evidence suggests that apoptosis activated by palmitate or stearate addition to cultured cells is correlated with de novo ceramide synthesis. Investigations in vitro strongly support that LC is able to inhibit the death planned, most likely by preventing sphingomyelin breakdown and consequent ceramide synthesis; this effect seems to be specific for acidic sphingomyelinase. The reduction of ceramide generation and the increase in the serum levels of insulin-like growth factor (IGF)-1, could represent 2 important mechanisms underlying the observed antiapoptotic effects of acetyl-LC. Primary carnitine deficiency is an uncommon inherited disorder, related to functional anomalies in a specific organic cation/carnitine transporter (hOCTN2). These conditions have been classified as either systemic or myopathic. Secondary forms also are recognized. These are present in patients with renal tubular disorders, in which excretion of carnitine may be excessive, and in patients on hemodialysis. A lack of carnitine in hemodialysis patients is caused by insufficient carnitine synthesis and particularly by the loss through dialytic membranes, leading, in some patients, to carnitine depletion with a relative increase in esterified forms. Many studies have shown that LC supplementation leads to improvements in several complications seen in uremic patients, including cardiac complications, impaired exercise and functional capacities, muscle symptoms, increased symptomatic intradialytic hypotension, and erythropoietin-resistant anemia, normalizing the reduced carnitine palmitoyl transferase activity in red cells.     

Carnitine as an essential nutrient

Carnitine performs a critically important role in energy metabolism and is synthesized in the healthy adult predominantly in the liver and kidney. The typical well balanced American diet contains significant amounts of carnitine as well as the essential amino acids and micronutrients needed for carnitine biosynthesis. Thus carnitine is an infrequent problem in the healthy, well nourished adult population in the United States. However, carnitine can be a conditionally essential nutrient for several different types of individuals. Preterm infants require carnitine for life-sustaining metabolic processes but have a carnitine biosynthetic capability that is not fully developed. There is an increasing number of documented problems with carnitine metabolism in preterm infants not receiving an exogenous source of carnitine indicating that endogenous biosynthesis of carnitine is not adequate to meet the infant's need. Children with different forms of organic aciduria appear to have a greatly increased need for carnitine to function in the excretion of the accumulating organic acids. This need exceeds their dietary carnitine intake and carnitine biosynthetic capability. Renal patients treated with chronic hemodialysis appear to lose carnitine via the hemodialysis treatment, and this loss cannot be repleted simply by endogenous biosynthesis and dietary intake. Treatment with drugs such as valproic acid and metabolic stresses such as trauma, sepsis, organ failure, etc, can also result in a requirement for exogenous carnitine. Accurate assessment of the carnitine status of patients at risk for carnitine deficiency is fundamental to the identification of those patients who require carnitine as the result of altered metabolism.     

Carnitine: an overview of its role in preventive medicine

Carnitine (beta-hydroxy-gamma-N-trimethylaminobutyric acid) is required for transport of long-chain fatty acids into the inner mitochondrial compartment for beta-oxidation. Widely distributed in foods from animal, but not plant, sources, carnitine is also synthesized endogenously from two essential amino acids, lysine and methionine. Human skeletal and cardiac muscles contain relatively high carnitine concentrations which they receive from the plasma, since they are incapable of carnitine biosynthesis themselves. Since the discovery of a primary genetic carnitine deficiency syndrome in 1973, carnitine has become the subject of extensive research. It is now recognized that carnitine deficiency may also occur secondary to genetic disorders of intermediary metabolism as well as to a variety of clinical disorders, including renal disease treated by hemodialysis, the renal Fanconi syndrome, cirrhosis, untreated diabetes mellitus, malnutrition, Reye's syndrome, and certain disorders of the endocrine, neuromuscular, and reproductive systems. Administration of the anticonvulsant valproic acid and total parenteral nutrition may also induce hypocarnitinemia. In many instances, the physiological implications of secondary carnitine deficiency have not been resolved. However, evidence for a specific carnitine requirement for the newborn, especially if preterm, is accumulating. Moreover, carnitine administration may have a favorable effect on some forms of hyperlipoproteinemia. Carnitine, now recognized as a conditionally essential nutrient, is a significant factor in preventive medicine.     

Postweaning carnitine supplementation of iron-deficient rats

Severe iron deficiency in the suckling and weanling rat is associated with lipid accumulation in serum and liver, impaired ketogenesis in the suckling pup and low levels of carnitine in some tissues. Carnitine has been effective in reducing high triacylglycerol levels in humans and rats. This study examined tissue triacylglycerol concentrations of iron-deficient rats supplemented with carnitine or iron. Iron-adequate (C) and iron-deficient (D) pups were weaned to diets containing 38 ppm Fe (c) or 6 ppm Fe (d) with or without 0.2% DL-carnitine (Carn) resulting in six experimental treatments: CcCarn, DdCarn, Cc, Cd, Dc, Dd. Males received the diets for 2 wk and female littermates for 4. After 2 and 4 wk, carnitine supplementation significantly increased carnitine content in liver, heart and skeletal muscle by 30-60% in rats from control and Fe-deficient dams. Carnitine treatment significantly lowered the triacylglycerol level in liver of 49-d-old Fe-deficient females, but did not affect other tissues at either time point compared to other dietary treatments. Fe supplementation did not increase carnitine content in tissues, but did reduce triacylglycerol levels in liver by 4 wk and in skeletal muscle at both time points. Possible mechanisms by which iron and carnitine may lower lipids are discussed.     

The effects of exercise training on γ-butyrobetaine hydroxylase and novel organic cation transporter-2 gene expression in the rat

The concentration of carnitine in plasma is generally increased with exercise training, suggesting that either carnitine biosynthesis is stimulated or renal reabsorption of carnitine is enhanced, or both. Carnitine, an essential cofactor in the oxidation of fatty acids, is released into the plasma following hydroxylation by γ-butyrobetaine hydroxylase (BBH), the final enzyme in the biosynthetic pathway found primarily in the liver. The organic cation transporter (OCTN2), the carnitine transporter found in kidney, is important in the distribution of carnitine by facilitating its renal reabsorption from urine. In this study, we tested the hypothesis that exercise training increases gene and protein expression of BBH and OCTN2, resulting in enhanced plasma carnitine levels. Male Wistar rats were subjected to 2 daily exercise sessions of treadmill running, 5?days per week, for a 10-week period. The concentration of total carnitine in plasma was significantly increased in trained rats compared with sedentary rats. In trained rats, mRNA and protein expression of BBH were increased in liver, whereas only BBH mRNA expression was increased in kidney. Liver of trained rats demonstrated increased mRNA and protein expression of OCTN2 compared with sedentary rats. In kidney of trained rats, however, only an increase in mRNA expression of OCTN2 was observed. Our results suggest that the improved plasma carnitine status in the trained rat is associated with increased carnitine biosynthesis in liver and kidney. The observation that OCTN2 expression was increased in kidney suggests a potential role of the kidney in the reabsorption of carnitine from the urine.     

Late onset primary systemic carnitine deficiency exacerbated by carnitine-free parenteral nutrition

We describe a 21-year-old male with previously normal plasma total and free carnitine levels who developed a deficiency manifest by decreased plasma and muscle total and free carnitine, decreased urine carnitine, severe hepatic steatosis, mediastinal lipomatosis, progressively impaired triglyceride clearance, myopathy and intermittent hypoglycemia. This case demonstrates that systemic carnitine deficiency may occur in some patients receiving long term carnitine-free TPN. Carnitine may be an essential element of the diet in this patient population.     

Chronic Dialysis Patients Are Depleted of Creatine: Review and Rationale for Intradialytic Creatine Supplementation

There is great need for the identification of new, potentially modifiable risk factors for the poor health-related quality of life (HRQoL) and of the excess risk of mortality in dialysis-dependent chronic kidney disease patients. Creatine is an essential contributor to cellular energy homeostasis, yet, on a daily basis, 1.6–1.7% of the total creatine pool is non-enzymatically degraded to creatinine and subsequently lost via urinary excretion, thereby necessitating a continuous supply of new creatine in order to remain in steady-state. Because of an insufficient ability to synthesize creatine, unopposed losses to the dialysis fluid, and insufficient intake due to dietary recommendations that are increasingly steered towards more plant-based diets, hemodialysis patients are prone to creatine deficiency, and may benefit from creatine supplementation. To avoid problems with compliance and fluid balance, and, furthermore, to prevent intradialytic losses of creatine to the dialysate, we aim to investigate the potential of intradialytic creatine supplementation in improving outcomes. Given the known physiological effects of creatine, intradialytic creatine supplementation may help to maintain creatine homeostasis among dialysis-dependent chronic kidney disease patients, and consequently improve muscle status, nutritional status, neurocognitive status, HRQoL. Additionally, we describe the rationale and design for a block-randomized, double-blind, placebo-controlled pilot study. The aim of the pilot study is to explore the creatine uptake in the circulation and tissues following different creatine supplementation dosages.     

epsilon-N-trimethyllysine availability regulates the rate of carnitine biosynthesis in the growing rat

Rates of carnitine biosynthesis in mammals depend on the availability of substrates and the activity of enzymes subserving the pathway. This study was undertaken to test the hypothesis that the availability of epsilon-N-trimethyllysine is rate-limiting for synthesis of carnitine in the growing rat and to evaluate diet as a source of this precursor for carnitine biosynthesis. Rats apparently absorbed greater than 90% of a tracer dose of [methyl-3H]epsilon-N-trimethyllysine, and approximately 30% of that was incorporated into tissues as [3H]carnitine. Rats given oral supplements of epsilon-N-trimethyllysine (0.5-20 mg/d), but no dietary carnitine, excreted more carnitine than control animals receiving no dietary epsilon-N-trimethyllysine or carnitine. Rates of carnitine excretion increased in a dose-dependent manner. Tissue and serum levels of carnitine also increased with dietary epsilon-N-trimethyllysine supplementation. There was no evidence that the capacity for carnitine biosynthesis was saturated even at the highest level of oral epsilon-N-trimethyllysine supplementation. Common dietary proteins (casein, soy protein and wheat gluten) were found to be poor sources of epsilon-N-trimethyllysine for carnitine biosynthesis. The results of this study indicate that the availability of epsilon-N-trimethyllysine limits the rate of carnitine biosynthesis in the growing rat.     

Conséquences de l'insuffisance rénale aiguë sur les métabolismes

Acute renal failure (ARF) is associated with a number of metabolic disturbances. ARF does not seem by itself to cause significant alterations of energy expenditure. It induces insulino-resistance and an increase in hepatic gluconeogenesis, which contribute to glucose intolerance. Disturbances of protein metabolism lead to hypercatabolism due to underlying diseases and to renal failure. These abnormalities are linked to ARF-induced metabolic acidosis or to renal failure per se (secretion of catabolic hormones, decrease in muscle protein synthesis, decrease in amino acid production from the kidney, protein losses due to dialysis). Finally ARF is associated with disturbances of lipid metabolism: decrease in lipolytic activity, increase in triglyceridemia, hypocholesterolemia and alterations of lipoprotein profile.These metabolic disturbances can induce malnutrition, which may contribute to the high mortality of ARF. However, assessing the proper role of renal failure remains difficult, and requires further prospective studies using multivariate analysis.