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Introduction

Sarcopenia is defined as a decrease in muscle strength and physical function and skeletal muscle mass depletion (1,2). Primary sarcopenia is caused by aging; secondary sarcopenia is caused by malnutrition, sedentary behavior, and various clinical conditions, such as inflammatory disease, endocrine disease, and liver disease (3,4). The prevalence of sarcopenia in patients with chronic liver disease (CLD) is ranged from 10 to 70% in Japan (4,5). Recent studies have revealed that sarcopenia exacerbates survival, quality of life, and outcome after liver transplant in patients with liver cirrhosis (LC) (6-12). Since hepatocytes perform the function of glucose, lipid, and protein metabolism, liver dysfunction causes a glycogen storage dysfunction in the liver that facilitates the utilization of glycogen and branched amino acid from skeletal muscle, resulting in the progression of proteolysis (13,14). Therefore, preventive treatment is needed to reduce the onset and progression of sarcopenia due to skeletal muscle depletion in patients with CLD.

Levocarnitine (L-carnitine) is an essential nutrient that plays a pivotal role in fatty acid metabolism (15). L-carnitine is involved in β-oxidation of fatty acids. It is a conditionally synthesized nutrient from amino acids methionine and lysine in the brain, liver, and kidney. Carnitine is obtained mainly from food; however, one-fourth of carnitine is synthesized in the kidney and liver (14,16). In other words, L-carnitine deficiency occurs more frequently in patients with LC or CLD. Several reports about L-carnitine administration in patients with LC revealed that it improved muscle cramps, suppressed hepatic encephalopathy, and improved hyperammonemia (17,18). Furthermore, L-carnitine administration may improve sarcopenia in patients with LC (14,19). However, enough evidence has not been obtained in previous studies. Thus, this study aimed to clarify the effect of L-carnitine administration on body composition [skeletal muscle mass and bone mineral density (BMD)] in patients with CLD.

Materials and methods

Study design and patients

In this retrospective study, we reviewed 592 patients with CLD between 2015 and 2018 at Saiseikai Niigata Hospital. Of those patients, 85 were treated with L-carnitine (Otsuka Pharmaceutical, Tokyo, Japan) and underwent computed tomography (CT) twice during L-carnitine administration. The interval of CT scans was within 6-18 months. These 85 patients met the following inclusion criteria: i) Subsequent CT scans were conducted within 6-18 months that enabled evaluation of the change in skeletal muscle mass and clinical parameters and BMD by dual energy X-ray; and ii) they continued L-carnitine administration during the observational period. Patients with hepatocellular carcinoma (HCC) were excluded (Fig. 1). In this study, the L-carnitine dose ranged from 1,500 to 3,000 mg/day, and the dose was selected by the attending physician. The reasons for L-carnitine administration were hepatic encephalopathy, muscle cramps, hyperammonemia, hypoalbuminemia, or combination of these conditions. We evaluated the effects of L-carnitine on body composition in patients with CLD. Moreover, 87 patients with CLD who did not receive L-carnitine and underwent paired CT scans to screen for HCC within 6-18 months were enrolled as controls. Cases (patients who received L-carnitine) and controls were matched for age, sex, body mass index (BMI), and serum albumin, using propensity score matching.

Figure 1 Patient flow chart. After screening 592 patients with chronic liver disease, 85 patients who were administered L-carnitine and 87 who were not administered L-carnitine were enrolled. After propensity score matching, 44 patients with L-carnitine administration were selected and 44 patients without L-carnitine administration were selected.

Evaluation for skeletal muscle mass and intramuscular adipose tissue content (IMAC)

Skeletal muscle mass was evaluated using the skeletal muscle mass index (SMI) on CT scans. The SMI was calculated as follows: The sum of the cross-sectional area of skeletal muscles at the level of the third lumbar vertebra (L3) was measured by a radiological technologist using a region of interest (ROI) precisely traced with the use of commercially available image analysis software (volume analyzer SYNAPSE VINCENT, Fujifilm Medical Co., Ltd.), and this value was divided by height squared (cm2/m2) (4). To evaluate the yearly change in SMI, ΔSMI/year (%) was calculated as follows: ΔSMI/year (%) = [(SMI on the second CT-SMI on the initial CT)/SMI on the initial CT x100/interval between CT (day)/365] (19). CT was typically conducted in patients with CLD every 6-12 months according to the guidelines of the Japan Society of Hepatology (20).

Muscle quality was examined as IMAC at the L3 level. As previously described, IMAC was calculated by dividing the CT attenuation value of the multifidus muscles by that of the subcutaneous fat (21). To evaluate the yearly change in IMAC, ΔIMAC/year was calculated as follows: ΔIMAC/year = [IMAC on the second CT-IMAC on the initial CT]/[interval between CT (day)/365].

Evaluation of BMD

All patients underwent scanning of the total lumbar spine (L2-L4) BMD (LSBMD), and whole body BMD (WBBMD) by dual energy X-ray absorptiometry (DEXA) at each CT. To evaluate the yearly change in both BMD, ΔBMD/year (%) was calculated as follows: ΔBMD/year (%) = [(BMD on the second DEXA-BMD on the initial DEXA)/BMD on the initial DEXA x100/interval between DEXA (day)/365].

Clinical and laboratory assessment

Patients underwent blood tests and CT on the same day. Clinical data were collected for the etiology of liver disease, BMI, and blood test results (white blood cells, platelet counts (Plt), serum albumin, aspartate aminotransferase (AST), alanine aminotransferase (ALT), cholinesterase, and hemoglobin A1c). The albumin-bilirubin (ALBI) score in each participant was calculated by the following formula as reported previously: ALBI score = [log10 total bilirubin (µmol/l) x 0.66] + [serum albumin (g/l) x -0.085], while ALBI grade was classified into the following: ALBI score ≤-2.60, grade 1; -2.60 <ALBI score ≤-1.39, grade 2; and ALBI score >-1.39, grade 3 (22,23). The fibrosis-4 index (FIB-4) in each participant was calculated by the following formula as reported previously: FIB-4 = age (years) x AST (IU/l) ÷ [platelets (109) x ALT (IU/l)] (24-26).

Statistical analysis

Continuous variables are presented as median and interquartile range (IQR) and analyzed using the Mann-Whitney U test. Categorical variables and nominal variables are presented as frequency (percentage) and analyzed using Fisher's exact test. We applied 1:1 propensity score matching to balance the assignment of patients with L-carnitine administration. The variables were age, sex, BMI, and serum albumin. Variables that affect sarcopenia were selected. Clinical features of CLD patients with sarcopenia were elderly, low BMI, and low albumin, and SMI depended on sex (27). Values of P<0.05 were considered statistically significant. All statistical analyses were performed using EZR ver. 1.37 (Saitama Medical Center, Jichi Medical University, Saitama, Japan) (28).

Results

Patient characteristics and body composition at baseline and endpoint

We enrolled 85 patients with L-carnitine administration and 87 control patients in this study and divided these patients into two groups, namely, patients with L-carnitine administration (LAG, n=44) and patients without L-carnitine administration (controls, n=44), by using propensity score matching for age, sex, BMI, and serum albumin. The overall characteristics (32 men and 56 women) are shown in Table I. The median age was 69 years (IQR, 64.0, 75.0). The median SMI was 37.4 cm2/m2 (IQR, 34.01, 44.34). The etiology of CLD was hepatitis B virus infection (n=10), hepatitis C virus infection (n=35), alcoholism (n=8), nonalcoholic steatohepatitis and nonalcoholic fatty liver disease (n=23), primary biliary cholangitis (n=5), autoimmune hepatitis (n=5), and others (n=2). No significant difference in variables were found between the LAG and controls at baseline as well as at the endpoint (Table II).

Table I Comparison of clinical and biochemical characteristics between the LAG and controls at baseline.

Table I

Comparison of clinical and biochemical characteristics between the LAG and controls at baseline.

Factor	All patients (IQR)	LAG (IQR)	Controls (IQR)	P-value
Number of patients	88	44	44
Age (years)	69.00 (64.00, 75.00)	70.50 (65.00, 75.25)	68.00 (64.00, 75.00)	0.523
Sex				0.829
Male	36	19	17
Female	52	25	27
Body mass index (kg/m2)	23.12 (20.71, 25.14)	23.39 (19.96, 25.99)	22.48 (21.43, 24.98)	0.507
Skeletal muscle mass index (cm2/m2)	37.40 (34.01, 44.34)	37.74 (34.17, 43.58)	37.16 (33.83, 44.34)	0.67
Intramuscular adipose tissue content	-0.20 (-0.30, -0.08)	-0.22 (-0.32, -0.10)	-0.19 (-0.27, -0.07)	0.309
Visceral fat area (cm2)	99.00 (61.79, 137.82)	90.47 (53.98, 125.77)	109.06 (77.08, 137.82)	0.313
Whole body bone mineral density (g/cm2)	0.94 (0.86, 1.04)	0.94 (0.86, 1.04)	0.95 (0.87, 1.02)	0.914
Lumber spine bone mineral density (g/cm2)	0.87 (0.75, 1.07)	0.87 (0.74, 1.05)	0.87 (0.78, 1.09)	0.599
Etiology				0.906
HBV	10	4	6
HCV	35	17	18
Alcohol	8	4	4
NASH and NAFLD	23	12	11
PBC	5	4	1
AIH	5	2	3
Other	2	1	1
ALBI score	-2.89 (-3.05, -2.70)	-2.88 (-3.05, -2.73)	-2.90 (-3.03, -2.68)	0.877
ALBI grade (1/2/3)				0.757
1	76	37	39
2	12	7	5
3	0	0	0
FIB-4 index	2.30 (1.66, 3.14)	2.62 (1.82, 3.51)	2.23 (1.58, 2.74)	0.123
White blood cells (x102/µl)	55.00 (46.00, 62.25)	55.50 (49.75, 63.50)	53.50 (44.75, 61.00)	0.251
Platelet counts (x104)	18.65 (7.10, 43.40)	17.95 (15.28, 21.38)	20.00 (15.00, 23.38)	0.307
Albumin (g/dl)	4.10 (3.98, 4.32)	4.15 (4.00, 4.30)	4.10 (3.90, 4.40)	0.943
Aspartate aminotransferase (U/l)	25.00 (21.00, 30.00)	25.00 (21.00, 31.50)	24.50 (19.00, 30.00)	0.435
Alanine aminotransferase (U/l)	17.00 (12.00, 25.00)	17.00 (12.00, 23.50)	17.00 (11.00, 25.00)	0.947
Cholinesterase (U/l)	297.00 (247.75, 340.00)	282.00 (237.75, 332.25)	297.50 (266.50, 353.25)	0.346
Triglyceride (mg/dl)	101.00 (73.00, 124.75)	107.50 (71.75, 143.75)	93.00 (73.25, 113.00)	0.335
γ-GTP (IU/l)	17.50 (13.00, 32.75)	18.00 (13.00, 35.50)	17.00 (1300, 30.50)	0.904
Total cholesterol (mg/dl)	186.00 (161.25, 212.00)	184.00 (161.75, 212.25)	186.50 (161.00, 210.00)	0.893
Hemoglobin A1c (%)	5.80 (5.50, 6.20)	5.80 (5.45, 6.20)	5.80 (5.53, 6.10)	0.711
Observational period (year)	0.98 (0.85, 1.10)	0.92 (0.74, 1.02)	0.99 (0.90, 1.23)	0.007

[i] Data were presented as number of patients or median (interquartile range). LAG, Levocarnitine administration group; HBV, hepatitis B virus; HCV, hepatitis C virus; NASH, nonalcoholic steato-hepatitis; NAFLD, nonalcoholic fatty liver disease; PBC, primary biliary cholangitis; AIH, autoimmune hepatitis; FIB-4, fibrosis-4; IQR, interquartile range; γ-GTP, glutamyl transpeptidase; ALBI, ALBI, albumin-bilirubin.

Table II Comparison of clinical and biochemical characteristics between the LAG and controls at endpoint.

Table II

Comparison of clinical and biochemical characteristics between the LAG and controls at endpoint.

Factor	All patients (IQR)	LAG (IQR)	Controls (IQR)	P-value
Number of patients	88	44	44
Skeletal muscle mass index (cm2/m2)	37.99 (32.98, 44.08)	39.58 (34.63, 44.46)	36.15 (32.43, 43.49)	0.166
Intramuscular adipose tissue content	-0.20 (-0.30, -0.07)	-0.22 (-0.33, -0.08)	-0.19 (-0.26, -0.08)	0.367
Visceral fat area (cm2)	102.48 (62.22, 137.26)	92.38 (58.48, 147.07)	114.33 (66.44, 135.65)	0.404
All bone mineral density (g/cm2)	0.93 (0.85, 1.03)	0.93 (0.86, 1.04)	0.93 (0.85, 1.02)	0.764
LS bone mineral density (g/cm2)	0.87 (0.76, 1.08)	0.86 (0.74, 1.05)	0.87 (0.78, 1.09)	0.384
ALBI score	-2.89 (-3.07, -2.73)	-2.83 (-3.05, -2.69)	-2.94 (-3.09, -2.77)	0.206
ALBI grade				0.352
1	76	36	40
2	12	8	4
3	0	0	0
FIB-4 index	2.20 (1.66, 2.88)	2.50 (1.88, 2.95)	2.12 (1.45, 2.73)	0.115
White blood cells (x102/µl)	58.00 (44.00, 70.25)	57.00 (42.75, 68.00)	59.00 (44.75, 70.50)	0.907
Platelet counts (x104)	19.65 (16.17, 23.30)	19.10 (15.35, 21.77)	20.20 (17.38, 25.72)	0.139
Albumin (g/dl)	4.20 (4.00, 4.40)	4.10 (3.90, 4.32)	4.25 (4.00, 4.40)	0.242
Aspartate aminotransferase (U/l)	24.00 (20.75, 29.25)	24.50 (21.00, 29.25)	23.50 (19.75, 28.00)	0.256
Alanine aminotransferase (U/l)	16.00 (12.00, 22.25)	17.00 (13.00, 23.25)	15.00 (10.75, 21.25)	0.171
Cholinesterase (U/l)	288.50 (250.50, 350.25)	282.00 (221.75, 332.50)	293.00 (254.75, 351.25)	0.138
Triglyceride (mg/dl)	94.00 (72.00, 123.75)	106.00 (72.00, 126.00)	92.00 (71.75, 121.75)	0.349
γ-GTP (IU/l)	16.00 (12.00, 32.00)	16.50 (12.75, 29.00)	16.00 (12.00, 32.25)	0.691
Total cholesterol (mg/dl)	180.00 (161.25, 206.75)	179.00 (162.75, 203.25)	181.00 (160.25, 212.00)	0.99
Hemoglobin A1c (%)	5.80 (5.50, 6.25)	5.80 (5.50, 6.30)	5.80 (5.70, 6.10)	0.971

[i] Data were presented as number of patients or median (interquartile range). LAG, Levocarnitine administration group; FIB-4, fibrosis-4; IQR, interquartile range; γ-GTP, glutamyl transpeptidase; ALBI, albumin-bilirubin; LS, lumbar spine.

Comparison of change in SMI and body composition between the LAG and controls

The initial CT showed similar median values of SMI for the two groups [37.74 (34.17, 43.58) and 37.16 (33.83, 44.34), P=0.67]. However, the median ΔSMI/year for the LAG and controls were 0.95% (-3.07, 6.10) and -2.34% (-5.34, 0.53), respectively (P<0.01) (Fig. 2A). The median ΔIMAC/year for the LAG and controls were -0.00 (-0.03, 0.03) and 0.01 (-0.02, 0.04), respectively (P=0.46) (Fig. 2B). The median ΔWBBMD/year for the LAG and controls were -0.24% (-1.20, 0.91) and -1.04% (-2.16, 0.47), respectively (P=0.04) (Fig. 2C). The median ΔLSBMD/year for the LAG and controls were -0.67% (-2.87, 1.80) and -0.18% (-1.99, 2.99), respectively (P=0.18) (Fig. 2D).

Figure 2 Comparison of ΔSMI/year, ΔIMAC/year, ΔWBBMD/year, and ΔLSBMD in the LAG and controls. (A) Comparison of ΔSMI/year in the LAG and controls. (B) Comparison of ΔIMAC/year in the LAG and controls. (C) Comparison of ΔWBBMD/year in the LAG and controls. (D) Comparison of ΔLSBMD in the LAG and controls. Data were analyzed with the Mann-Whitney U test. Values of P<0.05 were considered statistically significant. LAG, levocarnitine administration group; IMAC, intramuscular adipose tissue content; NS, not significant; SMI, skeletal muscle mass index; IMAC, intramuscular adipose tissue content; WBBMD, whole body bone mineral density; LSBMD, lumbar spine bone mineral density.

Discussion

Our results revealed that L-carnitine administration prevents skeletal muscle mass loss and osteoporosis. To our knowledge, this study is the first to report that L-carnitine may improve both sarcopenia and osteoporosis. Thus, the results of this study are of clinical significance for patients with CLD who have sarcopenia and osteoporosis.

The median ΔSMI/year in our results was 0.69% for all patients, 0.95% for the LAG and -2.34% for the controls. Especially, the median ΔSMI/year of the LAG was significantly better than that of the controls. According to previous studies, ΔSMI/year or Δ skeletal muscle area/year of patients with LC ranged from -2.2 to -0.22% (19,29). Our results show that skeletal muscle loss is suppressed compared with the results of these reports. In Japan, L-carnitine has been administered as a treatment for hepatic encephalopathy, hypoalbuminemia, and muscle cramps in patients with LC (17,18). Our study includes patients with CLD who take L-carnitine for various purposes. However, the skeletal muscle mass of the LAG was significantly increased, suggesting that L-carnitine may prevent skeletal muscle mass loss.

There are multiple hypotheses that carnitine administration suppresses skeletal muscle loss in patients with LC. Carnitine plays a central role in transporting long-chain fatty acids from the cytosol to the mitochondrial matrix. Carnitine binds to the long-chain acyl coenzyme A and is converted to acylcarnitine. Acylcarnitine is transported to the mitochondria and degraded by β-oxidation (14,30). Thus, carnitine administration improves energy metabolism disorders in the mitochondria in the liver (31). Improvement of these energy metabolism disorders is considered to suppress hyperammonemia in patients with LC (32). This is because the urea cycle, particularly localized in the liver, is a metabolic system that requires a lot of energy. Hyperammonemia activates myostatin and decreases muscle protein synthesis (33). Therefore, preventing hyperammonemia prevents skeletal muscle loss. Hiramatsu et al (19) reported that L-carnitine administration may suppress the progression of sarcopenia in conjunction with the improvement of hyperammonemia. The required dose of carnitine expected to inhibit the progression of sarcopenia is ≥1,274 mg/day (19), and the carnitine dose administered in this study (1,500-3,000 mg/day) exceeded that. However, since this is a retrospective study, serum ammonia was not measured in many cases. Prospective studies are needed to clarify the relationship between formed ammonia levels and skeletal muscle mass.

To date, carnitine administration has been suggested to increase lipid utilization in the skeletal muscle during low exercise and improve exercise performance (34). We considered that carnitine not only increased skeletal muscle mass but also improved the quality and examined changes in IMAC, the quality indicator of skeletal muscle (21), but did not yield significant results in our study. Studies reported that fatty infiltration of the muscle (myosteatosis) exacerbates hepatic encephalopathy in LC (35) and is a prognostic factor for liver transplant patients (21,36). Therefore, there is a need for treatments that improve not only skeletal muscle mass but also muscle quality. However, since the exercise and activity levels are not managed in this study, the effect of carnitine on IMAC may be unclear. In the future, a combination of carnitine and exercise may improve skeletal muscle quality.

Furthermore, our study suggested that carnitine administration may prevent BMD loss. The prevalence of osteoporosis in patients with LC cirrhosis is ~12-55%, which is higher than in healthy individuals (37). Along with sarcopenia, it is one of the issues that have a major influence on the health of patients with CLD. One of the mechanisms of osteoporosis in patients with CLD has been shown to activate osteoclasts by inflammatory cytokines (38). Because carnitine suppresses the production of inflammatory cytokines (39), it may have prevented the decrease in ΔWBBMD in our study. However, ΔLSBMD showed no significant effect. Further research is needed to treat osteoporosis in patients with CLD.

This study had several limitations. First, this was a retrospective single-center study with a small sample size. Moreover, the observation period was different for each patient. Second, the purpose and dose of L-carnitine administration were decided by the attending physician. Thus, prospective studies are warranted to clarify the effects of L-carnitine on preventing skeletal muscle loss in patients with liver disease.

In conclusion, we showed that L-carnitine administration prevented the loss of skeletal muscle mass and BMD in patients with CLD. L-carnitine administration can be a new option for treating osteoporosis and sarcopenia. Further detailed studies are needed to confirm this possibility.

Acknowledgements

Not applicable.

Funding

No funding was received.

Availability of data and materials

All data generated or analyzed in this study are included in this published article.

Authors' contributions

KO and TI designed the research; TI and TY conducted the research; AH, TH evaluated SMI, IMAC and BMD. MS collected the medication data. HN, HH, FK, MK, SH, and KS collected the clinical and laboratory assessment data; KO, TI, and YM analyzed the data; KO summarized the data; KO and TI wrote the manuscript. All authors have read, checked, and approved the final manuscript.

Ethics approval and consent to participate

The present study was conducted in accordance with the Declaration of Helsinki. Ethical approval was obtained from the ethics committees of Saiseikai Niigata Hospital (approval no. E17-27). Informed consent was obtained by the opt-out method on the website.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References