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The effect of L-carnitine therapy on anaemia therapy in paediatric patients on regular haemodialysis

Ghada M. El-Mashad
1
,
Mahmoud A. El-Hawy
1
,
Hebatallah M. NaserBahbah
1
,
Hanan M. Bedair
2
,
Marwa I. Habib
3

  1. Paediatric Department, Faculty of Medicine, Menoufia University, Egypt
  2. Clinical Pathology Department, National Liver Institute, Menoufia University, Egypt
  3. Lecturer in clinical pathology, National Liver Institute, Menoufia University, Egypt
Pediatr Pol 2021; 96 (4): 238–244
Data publikacji online: 2022/01/11
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INTRODUCTION

Patients with chronic kidney disease (CKD) have a relative erythropoietin (EPO) deficiency. This is considered as the main cause of anaemia in these patients. The severe form of CKD anaemia decreases quality of life and increases the risk of cardiovascular diseases such as left ventricular hypertrophy (LVH), depressed neurocognitive ability, reduced exercise capacity, progression of cardiovascular risk factors, and mortality in dialysis patients. So, the implementation of prevention and control measures is recommended [1-3].
Erythropoiesis-stimulating agents (ESAs) are generally used to control anaemia and reduce the need for blood transfusions in patients with CKD [1, 4]. Although ESAs are effective for reversing the anaemic status, the aetiology of anaemia is multifactorial due to other competing factors. The response capacity of these patients is variable [5-7]. The most common cause of erythropoietin resistance is reduced iron availability, including absolute and functional iron deficiency [8]. Hepcidin, a 25-amino-acid peptide predominantly produced by the liver, decreases the release of iron from storage tissues and causes a reduction in iron absorption from the gut. Therefore, hepcidin is involved in the pathogenesis of erythropoietin resistance [9]. Inflammation increases hepcidin production, limiting the availability of iron for erythropoiesis and thus providing a direct link between inflammation and erythropoietin resistance. The reduction of inflammation is a reasonable approach for treating erythropoietin resistance [10].
Carnitine is a hydrophilic amino acid that acts as a cofactor of long fatty-acid metabolism. It has an indirect role in glucose metabolism. This small molecule (162 D) is freely filtered by the glomerular membrane and reabsorbed by the proximal tubule via organic cation carnitine transporter 2 receptors, with a renal clearance of about 1–3 ml/min [11].
Carnitine participates in the de-acylation and re-acylation processes that remodel erythrocyte phospholipid membranes, stimulate erythropoiesis at high concentrations (> 200 µmol/l), increase the survival time of erythrocytes, and reduce oxidative stress via heme oxygenase 1 and inflammation [12].
Plasma carnitine levels decrease by about 80% by the end of a dialysis session. This depletion is restored after the session, from endogenous synthesis, cellular storage, and food intake. However, many factors affect the endogenous synthesis including dialysis of cofactors of carnitine synthesis, such as vitamin B6, niacin, vitamin C, lysine, and methionine, and protein malnutrition. Consequently, carnitine depletion develops immediately after the start of haemodialysis and increases with duration of dialysis. Furthermore, free carnitine is dialyzed at a higher rate than acylcarnitine. This tends to invert the plasma acyl/free carnitine level, which can exceed 0.4 [11].
Nutrition influences anaemia correction in haemodialysis by several pathways, including folic acid, vitamin B, vitamin C, carnitine, iron deficiencies, and a decrease in antioxidative capacity that produces a proinflammatory effect [13].

AIM OF THE STUDY

The aim of this work was to study the effect of L-carnitine (LC) supplementation with erythropoietin therapy in the treatment of renal anaemia in paediatric patients on regular haemodialysis.

MATERIAL AND METHODS

The study was carried out in the paediatric haemodialysis unit in the paediatric nephrology unit in Menoufia University and Clinical Pathology Department, National Liver Institute, Menoufia University during the period from March 2019 to September 2019. The study included 30 paediatric patients attending the paediatric haemodialysis unit with chronic renal failure on regular haemodialysis 3 times weekly for at least 3 months after obtaining written consent from their parents. The local ethics committee of Menoufia University approved the study protocol.

MATERIAL

The study included 30 paediatric Egyptian patients aged less than 18 years with chronic renal failure on regular haemodialysis for at least 3 months. The patients were divided into 2 groups: Group I included 15 patients receiving oral L-carnitine (LC) in a dose of 100 mg/kg per day in 3 divided doses – maximum 3 g per day, as described by Warady et al. [14], and erythropoietin therapy in a dose of 100-300 IU/kg 3 times per week. Group II received only erythropoietin therapy in a dose of 100-300 IU/kg 3 times per week, as described by Gagnadoux et al. [15]. The patients received about 5-10 blood transfusions prior to the study
Exclusion criteria: Patients with autoimmune disease, chronic haemolytic anaemia, or malignancy were excluded from the study.

ALL PATIENTS WERE SUBJECTED TO THE FOLLOWING:

Full patient history taking, including history of the original disease.
Clinical examination: full clinical examination including the following:
Vital signs: blood pressure was recorded and compared to the median (50th percentile) for age and sex using Egyptian standard growth charts.
Anthropometric measures: height and weight of the patients were recorded; both were compared to the median (50th percentile) for age and sex using Egyptian standard growth charts.

METHODS

By using sterile vein-puncture, 8 ml of venous blood was withdrawn from each patient and divided into 2 tubes. First, 4 ml blood was transferred into 2 EDTA tubes. The first one was used for CBC measurement performed on a Sysmex XT-1800i automated haematology analyser (Sysmex, Japan). The second EDTA tube was centrifuged for 10 min at 4000 rpm and stored at −80°C. Another 4 mL of blood was transferred into a plain tube and allowed to clot at 37°C and centrifuged for 10 min at 4000 rpm. Serum was used for determination of kidney function tests (urea and creatinine) using a Cobas e501 autoanalyser (Roche-Germany), iron profile (iron, total iron binding capacity “TIBC”, Transferrin saturation, Ferritin) on a modular Cobas 6000 c501 system (Roche-Diagnostics, Germany), and calcium (Ca) and phosphorus were done by AU480 chemistry analyser (Beckman Coulter Diagnostics).

Intact parathormone measurement

Determination of serum iPTH was done by enzyme-linked immunosorbent assay (ELISA) using a Human Parathyroid Hormone (PTH) ELISA Kit (INNOVA BIOTECH CO., Ltd., China). This ELISA kit uses a sandwich ELISA method. The Microelisa strip plate provided in the kit is pre-coated with an antibody specific to PTH. Standards or samples are added to the appropriate wells and combined to the specific antibody. Then a Horseradish Peroxidase (HRP)-conjugated antibody specific for PTH is added to each well and then incubated followed by a washing step to remove free components. The TMB substrate solution is then added to each well. Only wells that contain PTH and HRP-conjugated PTH antibody will appear blue in colour and turn yellow after the addition of the stop solution. The OD value is proportional to the concentration of PTH and is measured spectrophotometrically at a wavelength of 450 nm. We calculated the concentration of PTH in the samples by comparing the OD of the samples to the standard curve. Assay range was 3.3-200 pg/ml.

Adequacy of dialysis

The urea reduction ratio is a function of the clearance of urea from the blood by the dialyzer, the length of the individual dialysis treatment, and the volume of distribution of urea in a particular patient. Therefore, the urea reduction ratio is a quantitative measurement of an individual patient’s urea clearance during a single haemodialysis treatment and can be used as a proxy for the adequacy of solute clearance during a treatment [16, 17].
The urea reduction ratio as a measure of the adequacy of dialysis is calculated with the formula 100 × (1 − [Ct/Co]), in which Ct is the blood urea nitrogen measured 5 minutes after the end of dialysis and Co is the pre-dialysis blood urea nitrogen [18].
We also analysed serum levels of haemoglobin and erythrocytes, erythropoiesis-stimulating agent dose (ESA), and erythropoietin-resistance index (ERI) in U/Kg/g, which were calculated as the mean weekly adjusted dose of erythropoietin in units per kg body weight divided by the average haemoglobin in grams [19].
Measurements were made at the baseline and then on follow-up after 6 months.

Statistical analysis of data

The data were coded, entered, and processed on a computer using SPSS (version 24). The results were represented in tabular and diagrammatic forms and then interpreted. Mean, standard deviation, range, frequency, and percentage were used as descriptive statistics. The chi-square test and χ² test were used for the association variables for categorical data. Student’s t-test was used to assess the statistical significance of the difference between 2 population means in a study involving independent samples. The paired samples t-test was used to assess the statistical significance of the difference between 2 population means in a study involving paired samples. The p value was considered significant as follows: p > 0.05 – non-significant, p ≤ 0.05 – significant.

RESULTS

There were no statistically significant differences between studied groups regarding age, sex, height, weight, or BMI index centiles. There were no statistically significant differences between studied groups regarding differences in systolic or diastolic blood pressure centiles, implying good selection of cases (Table 1).
Table 2 showed no statistically significant difference regarding pre-dialysis serum urea and creatinine, post-dialysis urea and creatinine, urea reduction ratio (URR), calcium (Ca), phosphorus (P), and parathyroid hormone (PTH) between the studied groups. There were no statistically significant differences regarding iron profile between the studied groups.
The results shown in Table 3 reveal no statistically significant difference between the studied groups regarding haemoglobin level, mean erythropoietin-stimulating agent (ESA) dose, and mean erythropoietin-resistance index (ERI) before the start of L-carnitine supplementation. Six months after the addition of L-carnitine supplementation, there was a significant increase in haemoglobin level, while there were significant decreases in mean ESA dose and ERI in group I treated with L-carnitine and erythropoietin compared to Group II treated with erythropoietin only, in paediatric patients on regular haemodialysis.

DISCUSSION

Renal anaemia is a common complication of chronic kidney disease (CKD). The decline of renal function is associated with an increased incidence and severity of anaemia, and it affects more than 90% of patients with end-stage renal disease [20].
It not only affects the quality of life but also causes adverse cardiovascular events that can increase mortality [21, 22].
Deficiency of erythropoietin and iron are the main causes of anaemia in patients on regular haemodialysis [23]. The introduction of erythropoietin-stimulating agents dramatically improves renal anaemia. However, some patients do not respond effectively to these agents, which is known as erythropoietin (EPO) hyporesponsiveness or resistance [24].
Responsiveness to erythropoietin is affected by many factors such as serum albumin level, secondary hyperparathyroidism, inflammatory response, and iron deficiency [25]. There was a marked reduction in RBC survival in patients undergoing intermittent haemodialysis compared with healthy controls [26].
There are several actions of LC on circulating RBC suggesting that LC and carnitine palmitoyl transferase play a role in membrane phospholipid fatty acid turnover and may improve the viscoelastic properties of RBC by intervening on both the outer and the inner side of the erythrocyte membrane. Also, their anti-inflammatory activity is suggested to play a role in the prevention of apoptosis [27, 28].
So, we aimed to study the effect of L-carnitine (LC) therapy on anaemia and its treatment with erythropoietin therapy in paediatric patients on regular haemodialysis. We analysed serum levels of haemoglobin and erythrocytes, erythropoiesis-stimulating agent (ESA) dose, and erythropoietin-resistance index (ERI) calculated at baseline and then on follow-up after 6 months.
This study revealed no significant differences between the studied groups. However, we revealed that about 53.3% of all studied haemodialysis patients were male. This is in agreement with Tanvir et al., [29] who found that haemodialysis patients were more often male.
Regarding anthropometric measurements and the urea reduction ratio in our study, there was no statistically significant difference between the groups regarding demographic data. These results were in agreement with the study of Lotfy et al. [30]. This implies good selection of cases.
The present study showed that L-carnitine (LC) therapy improved anaemia in paediatric patients on regular haemodialysis in group I when compared to group II (treated with erythropoietin only). This agrees with Mortazavi et al., [31] who found that haemoglobin levels rose significantly in patients receiving oral L-carnitine (p = 0.04) but not in patients receiving placebo (p > 0.05). Also, Bellinghieri et al., [32] reported a significant increase in the haematocrit values at the end of a 2-month treatment with LC at dose of 2 g/day orally.
Similarly, Steiber et al., [33] found that a carnitine-treated group showed a statistically significant decrease in serum C-reactive protein and increase in blood haemoglobin, serum albumin, transferrin, and body mass index.
Furthermore, the addition of L carnitine to erythropoietin caused a significant decrease in mean use of ESA in group I treated with both L-carnitine (LC) and erythropoietin for 6 months when compared to group II treated with erythropoietin only. This agrees with Kletzmayr et al., [34] who reported that LC supplementation increased haemoglobin in haemodialysis patients without rHuEPO therapy and reduced rHuEPO requirements for the treatment of anaemia in haemodialysis patients.
These results agree with Murphy et al., [35] who suggested that L-carnitine would reduce the necessary EPO dose.
Similarly, Labonia [36] found a reduction in the rHuEPO requirement of the active group following LC intravenous administration after every dialysis session for 6 months (p < 0.02). Kletzmayr et al. [34] revealed that after 4 months of co-administration of LC and intravenous iron, the requirement of weekly rHuEPO dose was significantly decreased in haemodialysis patients (p < 0.001).
Also, in agreement with our results, Bilal Aoun et al. [37] analysed the effect of intravenous L-carnitine supplementation on the erythropoietin (EPO) requirement in 6 paediatric haemodialysis patients. They found increased Hb levels and decreased EPO requirement.
In contrast to our results, Sabry et al. [38] revealed no significant improvement in haemoglobin and erythropoietin dose after 6 months of addition of LC therapy to erythropoietin when compared to controls who received erythropoietin alone. This agrees with Vaux et al., [39] who could not demonstrate any beneficial effect of LC on renal anaemia. Also, Lilien et al. [40] found that there was no significant change in rhEPO requirement, haemoglobin level, and haematocrit during the study. They concluded that there was no beneficial effect of supplementation with L-carnitine on rhEPO requirement in children on dialysis.
This heterogeneity of results could be due to the difference in observation periods among these studies. Kopple [41] found that found that the erythropoietin dose was significantly decreased in patients supplemented with l carnitine (1 g/day orally for 4 months, p = 0.001), while they reported no significant increase in Hb concentrations.
In our study, an improvement of ERI was observed within 6 months after carnitine administration. This is in agreement with a study conducted by Savica et al., [42] who found that carnitine supplementation enhanced the response to the administered dose of erythropoietin in these patients, which ended in increased haemoglobin, reduced dose of required erythropoietin, and decreased index of erythropoietin resistance. This reduction of ERI strongly suggests that l carnitine supplementation might expand the erythrocyte lifespan.
The KDIGO guideline suggests not using adjuvants to an ESA such as vitamin C, vitamin D, vitamin E, folic acid, LC, or pentoxifylline because their evidence level was not sufficient [43]. The current study revealed that ESA and ERI had a statistically significant decrease after 3 months among Group 1 (receiving L-carnitine [LC] and erythropoietin therapy) but not among Group 2 (receiving erythropoietin therapy only).

CONCLUSIONS

L-carnitine may be used as an adjuvant therapy in paediatric haemodialysis patients to decrease the dosage of erythropoietin-simulating agents (ESA) and the erythropoietin-resistance index (ERI) while maintaining adequate levels of serum haemoglobin.
Limitations of the study: the sample size was small; prospective multi-centre studies on larger numbers of patients are recommended.

DISCLOSURE

The authors declare no conflict of interest.

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