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Experimental and Therapeutic Medicine logoLink to Experimental and Therapeutic Medicine
. 2015 Dec 29;11(3):1123–1127. doi: 10.3892/etm.2015.2964

Effects of L-carnitine supplementation on respiratory distress syndrome development and prognosis in premature infants: A single blind randomized controlled trial

MEHMET ADNAN OZTURK 1, ZEHRA KARDAS 2, FATİH KARDAS 3,, TAMER GUNES 1, SELİM KURTOGLU 1
PMCID: PMC4774440  PMID: 26998047

Abstract

The aim of the present study was to investigate the efficacy of L-carnitine therapy on the occurrence and prognosis of respiratory distress syndrome (RDS). A single blind, randomized controlled trial study was conducted on 130 infants with gestational ages of 28–36 weeks. Infants were assigned to experimental groups (groups 1 and 2) and control groups (groups 3 and 4). Groups 1 and 3 consisted of infants with RDS, and groups 2 and 4 groups were composed of infants without RDS. The experimental groups were treated with carnitine. No statistically significant differences in serum carnitine levels were detected between the study and the control groups on day 1 of treatment (P=0.06). However, on day 7 of treatment, serum carnitine levels in the experimental groups were significantly increased (P=0.02), as compared with the control groups. The surfactant requirement value, which is how many rounds of surfactant therapy were required, was 1.56±0.97 in group 1, and 2.12±0.99 in group 3 (P<0.001). The mean duration of mechanical ventilation required was 3.04±3.60 days in group 1, and 4.73±5.63 days in group 3 (P<0.001). The present results indicate that carnitine supplementation in premature infants with RDS may help to increase carnitine levels, thus decreasing the duration of mechanical ventilation and surfactant requirement.

Keywords: carnitine supplementation, respiratory distress syndrome, preterm, surfactant deficiency

Introduction

Respiratory distress syndrome (RDS) is among the most common diseases of preterm infants. RDS is caused by a decreased production or secretion of pulmonary surfactant (1). Deficient synthesis and release of surfactant is associated with asphyxia, hypoxaemia, pulmonary ischaemia, hypovolemia, hypotension and cold stress (1). Numerous causes of RDS have been identified, and the factors suspected to be involved in the pathogenesis of RDS are numerous (2). In recent years, studies have identified the presence of low serum carnitine levels in preterm newborns with RDS (2,3).

Carnitine is a hydrophilic amino acid derivative synthesized from lysine, which serves a crucial function in β oxidation as it transports long chain fatty acids across the mitochondrial membrane (4). Carnitine is essential for the fetus and is provided via placental transport. As the gestational age increases, fetal tissues store increasing amounts of carnitine; however, preterm infants are at an increased risk of carnitine deficiency due to low levels of α-butyrobetaine hydroxylase, a catalyzing enzyme in the final step of the carnitine biosynthetic signaling pathway (5,6). Therefore, preterm infants require exogenous carnitine supplementation for carnitine homeostasis (7). Human and cow milk-based infant formulas contain adequate amounts of carnitine for preterm infants; however, soya milk-based formulas and parenteral nutrition fluids are poor sources of carnitine (8). Therefore, preterm infants with a complicated birth or at <32 weeks of gestation have an increased risk of carnitine deficiency due to the challenges faced with enteral nutrition (8).

The effects of carnitine in preterm infants on nutritional or respiratory functions, specifically apnoea, have been studied in various trials (7,8). Two previous studies have demonstrated that free carnitine levels were reduced in infants with RDS compared with healthy controls (2,3). It has previously been demonstrated that, L-carnitine-betamethasone combination therapies significantly increase the dipalmitoyl phosphatidylcholine content of the foetal lungs and significant reduce the incidence of RDS and mortality in premature newborns, as compared with betamethasone alone (6,9).

The present study aimed to observe the efficacy of L-carnitine therapy with regards to the occurrence and prognosis of RDS, the duration of mechanical ventilation required, the amount of surfactant required, and the occurrence of bronchopulmonary dysplasia (BPD).

Materials and methods

Patients

The present study was a single blind, randomized controlled trial. Investigators and neonatologists were not provided information on the groups of patients, or informed of which patients received carnitine (Sigma-Tau, Rome, Italy). A total of 130 preterm infants (56 female and 74 male) that were observed in the neonatal intensive-care unit between January 2011 and January 2013 were included in the study. Written-informed consent was obtained from the parents of the infants. The protocol of the present study was approved by the ethics committee of the Erciyes University School of Medicine Faculty (Kayseri, Turkey). The gestational age of infants was calculated from the date of the last menstrual period of the mothers, confirmed using the New Ballard score (10).

Inclusion and exclusion criteria

The inclusion criteria for the study were as follows: Preterm infants with a gestational age of 28–36 weeks, and inclusion in the study within 6 h following birth. The exclusion criteria were as follows: Gestational age <28 weeks or >36 weeks, sepsis, asphyxia, congenital pneumonia or history of major congenital anomaly history, maternal gestational diabetes, maternal corticosteroid treatment (except for lung maturation) and transfusion with blood/blood products. Infants fulfilling the inclusion criteria were evaluated for RDS according to the following criteria: Respiratory rate >60/min during the 6 h following delivery; presence of gasping, sternal/intercostal retractions and cyanosis; hypoxemia, hypercapnia and acidosis on blood gas analysis; and compatible chest x-ray including reticulogranular patterns, air bronchograms and diffuse alveolar atelectasis. Clinical improvement during the first 12 h after birth suggests transient tachypnea of the newborn (TTNB), and onset after the first 24 h suggests pneumonia and sepsis (11). Patients with TTNB, pneumonia, sepsis or meconium aspiration syndrome were excluded from the present study. Diagnosis of BPD was performed according to the previously described criteria: Treatment with FiO2 >0.21 for ≥28 days and failure of the room air challenge test at 36 weeks' postmenstrual age (12).

Recording of patient characteristics

The mode of delivery of the infant, birth time, weight, gestational age, last menstruation date of the mother, maternal history of medication usage during gestation, hypertension and premature rupture of membranes were evaluated. Apgar scores, gender, twin births and presence of intrauterine growth restriction in the infants were also recorded (13).

Patient grouping

Preterm infants were separated into infants with RDS and infants without RDS, then randomized by blocks of four in a 1:1 ratio according to their admission time to the hospital for experimental and control groups (14). The infants included in the present study were divided into an experimental and a control group. The experimental group received carnitine treatment and the control group did not. Each group was subdivided into two subgroups of patients: An RDS group and a non-RDS group. The grouping was as follows: Group 1, RDS patients that received carnitine therapy; group 2, non-RDS patients that received carnitine therapy; group 3, RDS patients that did not receive carnitine therapy; and group 4, non-RDS patients that did not receive carnitine therapy. The experimental groups consisted of groups 1 and 2, and the control groups consisted of groups 3 and 4. In the experimental group, all patients (RDS and non-RDS) received daily carnitine treatment (30 mg/kg/day, 3 times/day) beginning from 6 h to 7 days. Carnitine was administered intravenously during parenteral feeding, and then via the enteral route when the patient began enteral feeding.

Treatment

All infants that were determined to have RDS were treated with nasal continuous positive airway pressure (NCPAP). The level of NCPAP for positive end expiratory pressure ranged from 6–8 cm H2O. Optiflow™ neonatal nasal cannulas and an Airvo 2 humidifier were used to generate NCPAP (both Fisher & Peykel Healthcare, Ltd., Auckland, New Zealand) (15). Infants with RDS that required an FiO2 of >0.35–0.40 and CPAP to sustain optimal blood O2 saturation (PaO2, >50–80 mmHg), SpO2 of 88–93% [as determined via a Nellcor N-600 pulse oximeter (v1.1.2.0; Covidien Boulder, CO, USA)], or had arterial/alveolar oxygen tension ratio PaO2/PAO2 (a/A) of <0.22 were intubated using an endotracheal tube (internal diameter, 3.0 mm), ventilated using an SLE 2000 (SLE Co., Croydon, UK) according to the synchronized intermittent mandatory ventilation method and provided with surfactant replacement therapy (Survanta®; Abbott Laboratories, Abbott Park, IL, USA). The total dose of surfactant was 100 mg phospholipids/kg birth weight (4 ml/kg), which was subsequently divided into four quarter-dose aliquots. Each of the four aliquots were administered in a different position, as follows: Head and body inclined 5–10° with head turned to the right and left, respectively; and head and body declined 5–10° with head turned to the right and left, respectively. Surfactant replacement therapy was administered intratracheally by instillation through a 5 French end-hole catheter (16). Surfactant replacement therapy was repeated after 6–24 h when improvement of clinical and laboratory RDS results were not observed (≥3 doses). The patients were then subjected to NCPAP following the improvement of their respiratory condition. The aim of the therapy was to maintain an a/A ratio of >0.22, SpO2 of 88–93% and PaO2 of 50–80 mmHg (17,18).

Carnitine analysis

Carnitine levels were measured in the plasma samples collected from all patients during the first 6 h following birth and on day 7 following birth. Standard carnitine kits (Z13010; Eureka Lab Division S.r.l., Chiaravalle, Italy) were used for the analysis of carnitine levels. The present method facilitated the analysis of the plasma levels of L-carnitine base (free) via a specific derivatization solution, separation by high pressure liquid chromatography (Agilent 1100; Agilent Technologies GmbH, Waldbronn, Germany) and subsequent quantification using fluorimetry.

Statistical analysis

The results are expressed as the mean ± standard deviation. A Kolmogorov-Smirnov test was used to determine the normality of the data. Statistical differences between the groups were analyzed using Student's t-test. Discrete variables were compared using a Pearson χ2 test. The Pearson correlation test was used to determine the correlations among the variables. Data analysis was performed using SPSS software, version 17.0 (SPSS, Inc., Chicago, IL, USA).

Results

Patient characteristics

A total of 130 preterm infants, including 56 females and 74 males, were enrolled in the present study. The mean gestational age was 32.8±2.9 weeks (range, 28–36 weeks). The average birth weight of the infants was 1,645.4±304.6 g; the mean birth weight for the experimental group infants was 1,639.2±322.7 g and that of the control group infants was 1,631.3±299.8 g. Baseline characteristics of the infants with and without RDS are presented in Table I.

Table I.

Characteristics of infants with or without RDS.

Experimental groups (1 and 2) Control groups (3 and 4)


Parameter RDS (n=30) Non-RDS (n=35) RDS (n=31) Non-RDS (n=34)
Day 1 carnitine (µmol/l) 22.6±3.1 25.5±3.2 22.0±3.7 24.3±2.6
Gender (Male/female) 17/13 20/15 18/13 19/15
Birth weight (g) 1,650.2±328.3 1,630.1±282.2 1,670.4±311.4 1,610.2±283.6
Gestational age (weeks) 33.3±1.8 33.1±2.9 33.1±1.7 32.8±2.6
Maternal age (years) 26.8±3.5 27.4±3.8 25.9±3.7 28.1±2.6
Apgar score
  1 mina 7 (6–8) 7 (6–9) 7 (5–8) 7 (6–8)
  5 mina 9 (8–10) 9 (8–10) 9 (8–10) 9 (7–10)
Cesarean section 21 (70%) 20 (57%) 22 (71%) 15 (54%)
Parity (n)a 2 (1–4) 3 (2–5) 2 (1–3) 3 (2–4)
a

Median (range). RDS, respiratory distress syndrome.

Carnitine levels

Following comparison of serum carnitine levels, no significant difference was observed on day 1 of measurements; however, on day 7 the carnitine levels were significantly higher in the experimental groups, as compared with the control groups (P=0.02; Table II).

Table II.

Carnitine levels of the experimental (1/2) and control (3/4) groups on days 1 and 7 following birth.

Carnitine level (µmol/l)

Day Experimental (n=65) Control (n=65) P-value
1 24.1±3.5 23.1±3.4 NS
7 18.8±2.3 11.9±2.2 0.02

NS, not significant.

When all patients were compared (experimental and control, RDS and non-RDS groups) for carnitine levels on days 1 and 7, it was observed that in the non-RDS group carnitine levels were significantly higher compared with the RDS group (P=0.01; Table III).

Table III.

Carnitine levels in the RDS (1/3) and non-RDS (2/4) groups on days 1 and 7 following birth.

Carnitine level (µmol/l)

Day RDS (n=61) Non-RDS (n=69) P-value
1 21.3±3.4 26.0±3.0 0.01
7 14.5±2.2 17.2±2.0 0.01

RDS, respiratory distress syndrome.

On day 1 the serum carnitine levels of all patients were evaluated, and no correlation was observed between carnitine levels and gender. However, a negative correlation between carnitine levels and birth weight and a positive correlation between carnitine levels and Apgar scores was observed. Serum carnitine levels therefore increased as birth weight decreased, and increased in positive correlation with Apgar scores (Table IV).

Table IV.

Correlation between carnitine levels, birth weight and Apgar score.

Parameter Correlation coefficient (r) P-value
Birth weight −0.51 0.01
Apgar score   0.26 0.02

Effects of carnitine therapy

The surfactant requirement values, which were the number of rounds of surfactant therapy required, were 1.56±0.97 and 2.12±0.99 in groups 1 and 3, respectively (Table V). Statistical comparison indicated that group 1 (RDS treated with carnitine) required significantly less surfactant compared with group 3.

Table V.

Surfactant therapy, MV and BPD development in patients with RDS in the experimental and control groups.

Parameter Group 1 (n=30) Group 3 (n=31) P-value
Surfactant (n)   1.56±0.97   2.12±0.99 <0.001
Patients requiring surfactant (n) 12 (40%) 17 (55%) <0.001
MV duration (days) 3.04±3.6 4.73±5.6 <0.001
Carnitine level (µmol/l)
Day 1 22.6±3.1 22.0±3.7 NS
Day 7 16.3±2.7 12.8±2.8 <0.001
Patients with BPD (n) 2 4 NS

MV, mechanical ventilation; BPD, bronchopulmonary dysplasia; RDS, respiratory distress syndrome; NS, not significant.

The mean durations of mechanical ventilation support were 3.04±3.6 and 4.73±5.63 days in groups 1 and 3, respectively. The mean duration of mechanical ventilation was therefore significantly reduced in group 1, compared with group 3 (P<0.001; Table V). A total of 12 patients (40%) in group 1 required mechanic ventilation and surfactant (mechanical ventilation and surfactant therapy criteria are the same), while 17 patients (55%) required mechanic ventilation and surfactant therapy in group 3 (P<0.001; Table V).

BPD was observed in 2 patients in group 1 and 4 patients in group 3, although this was not statistically significant (P=0.07).

Discussion

Previous studies have demonstrated that carnitine is crucially involved in the development of RDS and the carnitine status of patients with RDS (2,3,19). The results of the present study indicated that the duration of mechanical ventilation and the requirement for surfactant therapy was significantly reduced in the groups that received L-carnitine treatment, as compared with the control groups. A similar study was conducted by Crill et al (20), who reported that the requirement for mechanical ventilation, duration of ventilator use, and the incidence of BPD was not significantly different between the therapy and placebo groups. In the present study, BPD incidence was decreased in the groups treated with L-carnitine, although this difference was not statistically significant. Therefore, the results of the current study were not concordant with those reported by Crill et al (20). This may be due to the difference in carnitine dosage. Crill et al (20) used L-carnitine at a dosage of 20 mg/kg/day for all infants; however, in the present study a dose of 30 mg/kg/day was used. In all patients with RDS, carnitine levels were higher on day 7 in the groups treated with carnitine, as compared with the control groups, although this difference was not statistically significant. In a previous study that did use carnitine treatment, the levels of carnitine were significantly higher in patients without RDS (2).

In the present study, infants with RDS that were treated with L-carnitine exhibited a decreased serum carnitine concentration compared with non-RDS patients on days 1 and 7. These results were concordant with those of previous studies that investigated serum L-carnitine levels in patients with or without RDS (2,3). In the present study, serum carnitine levels on day 1 were not associated with the gender of the patients, but did show a negative correlation with birth weight and a positive correlation with Apgar scores. This may due to the increased requirement for surfactant synthesis in low birth weight infants as compared with infants with high Apgar scores that exhibit a healthy respiratory pattern. In two previous studies (2,3), no significant differences were reported between L-carnitine levels and gender, birth weight and Apgar scores. Patients with RDS treated with L-carnitine did not exhibit higher serum carnitine levels on day 7 compared with the control group.

It has been previously proposed that L-carnitine administered to RDS patients may be used for surfactant synthesis (5,6,19). Antenatally-administered carnitine has been demonstrated to accelerate the maturation of fetal lungs in rabbits (5). Furthermore, treatment of pregnant rats with carnitine resulted in a significant increase in total phospholipids and dipalmitoylphosphatidylcholine levels in fetal rat lungs (19,21). Palmitoylcarnitine is a form of carnitine that has been reported to have properties as a surface active molecule or surfactant, and functions as an intermediate in mitochondrial fatty acid oxidation (22). Palmitoylcarnitine may decrease the surface tension of the alveoli, and deficiency in palmitoylcarnitine may lead to the development of RDS.

In the present study, patients with RDS treated with carnitine had better results compared with the untreated group, including: Reduced surfactant requirement values; decreased number of patients requiring surfactant; shorter durations of mechanic ventilation; and fewer incidences of BPD. The data demonstrated the efficacy of treatment with L-carnitine and the consequences of carnitine deficiency. The transport of L-carnitine to the lungs of the premature infant likely increases for surfactant synthesis, and this may cause the reduced serum levels of carnitine observed in patients with RDS. Following birth there is a marked increase in energy metabolism. Premature infants with RDS require more energy due to their increased respiratory effort (23,24). It is well-established that carnitine serves a crucial function in cellular metabolic processes, such as aerobic catabolism of glucose and β oxidation of free fatty acids (23,24). Due to its role in metabolism, the diaphragmatic muscle requires carnitine for contractility (25). Premature infants may have lower glycogen levels, and therefore use more carnitine for fatty acid oxidation, leading to a decrease in carnitine levels.

In the present study, infants with a gestational age of 8–32 weeks had higher serum L-carnitine levels on the first day following birth compared with those with a gestational age of 32–36 weeks. Previous studies conducted by Meyburg et al (26) and Giannacopolou et al (27) reported a negative correlation between gestational age and serum carnitine concentrations. Conversely, Ozturk et al (2) did not establish a correlation between carnitine and gestational age.

The present study included a number of limitations. The carnitine levels of the mothers were not evaluated during the gestational period, and maternal carnitine levels may have affected carnitine levels in the infants. In addition, carnitine levels in the lung tissue of the infants were not examined.

The treatment dose of carnitine was 30 mg/kg in the current study; however, higher doses should be used in future studies.

Surfactant replacement requirement in RDS patients was significantly different in the group treated with carnitine, as compared with the control group. Therefore, the group treated with L-carnitine required less surfactant, which may decrease the number of complications and provide more cost-effective therapy. A total of 12 patients (40%) in group 1 required mechanic ventilation and surfactant replacement therapy, while a significantly greater number of patients (17 patients; 55%) required mechanic ventilation and surfactant therapy in group 3. Zaharia et al (28) reported that 54% of preterm infants >28 weeks of gestational age that received prophylactic NCPAP required mechanical ventilation.

In conclusion, the results of the present study suggested that early carnitine therapy should be administered to infants with RDS, as it is known to increase the synthesis of surfactant. Treating premature infants with RDS with carnitine may allow decreased duration of mechanical ventilation, the use of less surfactant, and decreased occurrence of BPD. L-carnitine levels are important in patients with RDS as they have decreased levels of surfactant, low production of energy, and weakness of diaphragm muscle contractibility (2,23). Further studies are required in larger populations to further examine the therapeutic and antenatal prophylactic use of L-carnitine in preterm infants with RDS.

Acknowledgements

The present study was supported by the Scientific Research Center of Erciyes University (grant no. TSU-11-3539)

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