http://orcid.org/0000-0002-9239-6932
Figures
Abstract
Objective
Leptin plays a role in stimulating vascular inflammation, vascular smooth muscle hypertrophy, and augmenting blood pressure, which contributes to the pathogenesis of atherosclerosis and leads to arterial stiffness. This vascular damage, measured by carotid-femoral pulse wave velocity (cfPWV), is recognized as an independent predictor of cardiovascular mortality in hemodialysis (HD) patients. The aim of this study was to evaluate the relationship between serum leptin and arterial stiffness in HD patients.
Patients and methods
In 112 of the 126 HD patients were eligible and their biochemical data were collected for analysis. Serum leptin level was measured using a commercial enzyme-linked immunosorbent assay kit. Carotid-femoral pulse wave velocity was measured by a validated tonometry system (SphygmoCor). Those have cfPWV values above 10 m/s are defined as the high arterial stiffness group.
Results
Among the participants, thirty-eight of them who were in the high arterial stiffness group, had a higher prevalence of diabetes mellitus (p = 0.002), age (p = 0.029), body mass index (BMI, p = 0.018), body fat mass (p = 0.001), hemoglobin (p = 0.040), and serum leptin levels (P<0.001). Multivariable logistic regression analysis showed that leptin (odds ratio [OR] 1.09; 95% confidence interval [CI] 1.04–1.14; p <0.001), diabetes (OR 7.17; CI 1.39–37.00; p = 0.019), body fat mass (OR 1.16; CI 1.02–1.33; p = 0.027); and hemoglobin (OR 2.11; CI 1.15–3.87; p = 0.015) were independently associated with arterial stiffness in HD patients.
Citation: Kuo C-H, Lin Y-L, Lee C-J, Wang C-H, Lai Y-H, Liou H-H, et al. (2018) Hyperleptinemia positively associated with central arterial stiffness in hemodialysis patients. PLoS ONE 13(1): e0190694. https://doi.org/10.1371/journal.pone.0190694
Editor: Abelardo I. Aguilera, Hospital Universitario de la Princesa, SPAIN
Received: May 12, 2017; Accepted: December 19, 2017; Published: January 5, 2018
Copyright: © 2018 Kuo et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This study was supported by a grant from Ministry of Science and Technology, Taiwan, MOST-104-2314-B-303-010 (https://www.most.gov.tw/). The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Advanced chronic kidney disease provides several mechanisms responsible for the exacerbation of cardiovascular disease, which includes the activation of the renin-angiotensin system, oxidative stress, elevated asymmetric dimethylarginine (ADMA), inflammation, dyslipidemia and vascular calcification. Vascular calcification, caused by increased calcium and phosphate loading, can lead to arterial stiffness. Carotid and aortic stiffness independently predict death in adult patients with end-stage renal disease (ESRD) [1–2]. In fact, this accelerated cardiovascular disease accounted for more than one -half of death in these patients. Therefore, it is important to explore this central arterial stiffness in ESRD patients. Carotid-femoral pulse wave velocity (cfPWV) is applied as one of the measurements for arterial stiffness and higher pulse wave velocity value predicts poor cardiovascular outcomes [3–4].
Leptin, one of the adipokines, is known to regulate various physiological processes including neuroendocrine functions, appetite, energy expenditure, glucose homeostasis, and insulin sensitivity. Recently, by increasing sympathetic tone and thus elevating blood pressure, leptin was found to be related to atherosclerosis in patients with cardiovascular disease [5]. Furthermore, through the inhibition of endothelial nitric oxide synthase, leptin was also related to coronary artery calcification in non-diabetic individuals [6]. However, this correlation between serum leptin level and arterial stiffness was uncertain in ESRD patients.
Therefore, this study is aimed to assess the association between the serum leptin level and arterial stiffness in hemodialysis (HD) patients.
Materials and methods
Patients
Patients older than 20 years of age, who underwent three HD sessions each week for at least six months at a single medical center in Hualien, Taiwan, were recruited between March and July in 2015. The study was conducted in accordance with the Declaration of Helsinki and was approved by the Protection of Human Subjects Institutional Review Board of Tzu-Chi University and Hospital. The approval number was IRB103-136-B. Informed written consent was obtained from all patients prior to their enrollment in this study. The estimating sample size should be more than 108 to meet the power of 90%. Participants suffered from acute infection, acute myocardial infarction, or pulmonary edema at the time of blood sampling were excluded.
Anthropometric analysis
Before dialysis session, bioimpedance measurement of fat mass was performed at the bedside according to the standard tetrapolar whole body (hand-foot) technique, using a single-frequency (50-kHz) analyzer (Biodynamic-450, Biodynamics Corporation, Seattle, USA). Body height was measured to the nearest half centimeter. Waist circumference was measured at the shortest point below the lower rib margin and the iliac crest to the nearest half centimeter. The post-HD body weight was recorded by half-kilogram with the patient in light clothing and without shoes after HD. The weight (kilograms) divided by height squared (meters) yielded body mass index (BMI). All the measurements were carried out by the same operator. Percentage of fat mass was analyzed by specific formula supplied by the manufacturer [7–10].
Biochemical measurement
Approximately 0.5 mL of blood samples were drawn for hemoglobin and white blood cells counts (Sysmex K-1000, Sysmex American, Mundelein, IL, USA) and the rest of 4.5 mL were immediately centrifuged at 3000 × g for 10 min for biochemical analyses. Within one-hour of collection, serum samples were stored at 4°C. Blood urea nitrogen, serum creatinine, glucose, total cholesterol, triglyceride, iron, total iron-binding capacity, ferritin, total calcium, and phosphorus were measured by using an autoanalyzer (COBAS Integra 800, Roche Diagnostics, Basel, Switzerland); serum leptin concentration by a commercially available enzyme immunoassay (EIA; SPI-BIO, Montigny le Bretonneux, France) [10]. Serum intact parathyroid hormone levels (iPTH) were tested using an enzyme-linked immunosorbent assay (ELISA; Diagnostic Systems Laboratories, Webster, Texas, USA) [9–10].
Carotid-femoral pulse wave velocity (cfPWV) measurement
As previously described, after 10 minutes rest in a quiet, temperature-controlled room, the participant was under a supine position during the measurement [7–10]. We applied a pressure tonometer (SphygmoCor system, AtCor Medical, Australia) to measure cfPWV between carotid and femoral sites and to record the pressure pulse waveform in the underlying artery transcutaneously. The integral software taped each set of the pulse wave and electrocardiography (ECG) data and calculated the mean time differences between the R-wave. Records were documented simultaneously with an ECG signal, which provided an R-timing reference. This measurement took ten consecutive cardiac cycles in average. The cfPWV was calculated by distance and the mean time difference between the two recorded arterial sites. Quality indices, included in the software, were constructed to ensure the uniformity of data. In this study, patient whose cfPWV values above 10 m/s is defined as high arterial stiffness group, according to the European Society of Hypertension and the European Society of Cardiology (ESH-ESC) 2013 Guidelines [11].
Statistical analysis
Data were tested for normal distribution using the Kolmogorov-Smirnov test. Data were expressed as mean ± standard deviation (SD) for normally distributed data and data were expressed as median and interquartile ranges for non-normal distributed data. Comparisons between patients were performed using the Student’s independent t-test (two-tailed) for normally distributed data, or the Mann-Whitney U test for parameters that presented a non-normal distribution. The glucose, ferritin, triglyceride, iPTH, leptin and HD duration datasets showed skewed non-normal distributions and therefore these were recalculated by transformation to the logarithm to the base 10; after this transformation the log-glucose, log-ferritin, log-triglyceride, log-iPTH, log-leptin, and log-HD duration then became normally distribution. Data expressed as the number of patients was analyzed by the χ2 test. Clinical variables that correlated with log-leptin levels in HD patients were evaluated by univariable linear regression analysis. Variables that were significantly associated with arterial stiffness in HD patients were tested for independence by multivariate logistic regression analysis. All statistical analyses employed SPSS for Windows (version 19.0; SPSS Inc., Chicago, IL, USA). A p-value < 0.05 was considered statistically significant.
Results
A total of 126 HD patients were enrolled, and 14 of them were excluded on account of withdrawing consents (N = 7), HD duration < 6 months (n = 2), HD twice per week (n = 2), acute infection (n = 1), acute myocardial infarction (n = 1), and pulmonary edema (n = 1). In 112 HD patients, 57 males and 55 females, were eligible for this study (Fig 1). Their mean age was 62.54 ± 13.52 years, 45 patients (40.2%) had diabetes and 58 patients (51.8%) had hypertension. The median HD duration was 4.63 (1,80–10.32) years. Clinical and laboratory characteristics of the HD patients are shown in Table 1. Thirty-eight patients (33.9%) were defined as high arterial stiffness, while 74 patients (66.1%) as low arterial stiffness. Compared to the low arterial stiffness group, the high arterial stiffness group had older age, higher post dialysis body weight, BMI, waist circumference, and body fat mass. Laboratory data included hemoglobin, triglyceride, and serum leptin levels were also significantly higher in the high arterial stiffness group. The calcium, phosphate, and intact PTH levels had no significant difference between two groups.
Distribution of HD patients in either high or low arterial stiffness subgroup is presented in Table 2. Therapeutic agents prescribed for our HD patients included angiotensin-converting enzyme (ACE) inhibitors, angiotensin receptor blockers (ARB), β-blockers, calcium channel blockers (CCB), statin, and fibrate were also listed. High arterial stiffness group had a higher percentage of diabetes. However, there was no statistically significant difference by subgroup analysis in gender, presence of hypertension, and use of ACE inhibitor, ARB, β-blockers, CCB, statin, or fibrate.
The association between clinical characteristics and serum leptin level is demonstrated in Table 3. There was no statistically significant difference on the leptin level by subgroup analysis in gender, presence of diabetes and hypertension, and use of ACE inhibitor, ARB, β-blockers, CCB, statin, or fibrate.
The correlation between serum leptin levels and clinical variables among 112 HD patients is depicted in Table 4. The univariate linear regression analysis revealed a positive correlation between log-leptin and post-HD body weight, waist circumference, BMI, body fat mass, cfPWV, aortic diastolic blood pressure (DBP), WBC counts and log-triglyceride in our HD patients. After multivariate stepwise linear regression analysis adjusting waist circumference, body mass index, body fat mass, carotid-femoral PWV, aortic DBP, WBC, and log-triglyceride, only body mass index, body fat mass and cfPWV were positively correlated with log-leptin level.
While, after multivariable logistic regression analysis of the variables (adopted factors: diabetes, age, waist circumference, body mass index, body fat mass, hemoglobin, triglyceride, leptin, SBP and DBP) showed that diabetes (odds ratio [OR], 7.17; 95% confidence interval [CI], 1.39–37.00; p = 0.019), body fat mass (OR 1.16; CI 1.02–1.33; p = 0.027); hemoglobin (OR 2.11; CI 1.15–3.87; p = 0.015); and leptin (OR 1.09; CI 1.04–1.14; p = <0.001) were independently correlated to central arterial stiffness in our HD patients (Table 5).
Discussion
After adjusting age, diabetes, body mass index, body fat mass, body weight, hemoglobin, triglyceride, leptin, systolic and diastolic blood pressure in multivariable logistic regression analysis, our study found that central arterial stiffness was positively associated with leptin, diabetes, hemoglobin, and body fat mass. This finding demonstrated the coherence of hyperleptinemia and progressive arterial stiffness in ESRD patients. This association of leptin and arterial stiffness had also been shown in geriatrics, obese, or healthy population [12–14]. Moreover, our published data had delineated this association in kidney transplantation recipients [15–16].
Even the decrease of renal clearance can augment serum leptin concentration in ESRD patients [17]; however, one-quarter of chronic peritoneal dialysis patients maintained normal serum leptin level [18]. Therefore, the determinate factors of serum leptin level in ESRD subjects should be multivariate and beyond. Similar to non-dialysis population, high serum leptin level in our HD patients also corresponded with BMI and percentage of body fat mass, which support this hypothesis. An overproduction of leptin from adipose tissue may contribute to this hyperleptinemia.
Leptin had been found to able to trigger hypertension in various animal and clinical studies, thus can exacerbate atherosclerosis in cardiovascular disease [19]. Meanwhile, alpha antagonist, through the inhibition of leptin-induced sympathetic tone, was proved to reverse this high blood pressure in rat [20–21].
Before our findings, there is only one study discussed the leptin level and arterial stiffness in ESRD subjects [22]. However, this study discovered an inverse relationship between leptin and arterial stiffness, which was opposite not only to our study which focuses on HD patients, but also to the other studies on populations without kidney disease. The authors implied both acidosis status and obesity were responsible for this conflicting result. However, two questions were left to be clarified. First, among many different methods to measure arterial stiffness, only carotid-to-femoral PWV has been shown to have a predictive value for morbidity and mortality and became widely used [23]. Raikou et al. presented leptin was only inversely associated with carotid augmentation index (AIx), but not with PWV. Second, the study grouping was based on the leptin levels, instead of PWV values. The cfPWV value above 10 m/s was broadly validated with poor clinical outcome, while the cut-off point to defined hyperleptinemia was unclear.
Leptin was considered to be an antidiabetic adipokine because of its well-known effect on appetite suppression and energy regulation via thalamus. With more understanding of the function of leptin receptor in different organs, the impact of leptin is more than on energy metabolism [24]. In our HD population, more diabetic patients were in the high arterial stiffness group. The multivariate logistic regression analysis disclosed that diabetes had the strongest correlation to arterial stiffness beyond other factors. The result is consistent with the previous studies focus on non-ESRD diabetic patients [25–26].
In addition, the current study found hemoglobin level was correlated with arterial stiffness. This finding was similar to previous reports based on a large healthy Japanese cohort and on HD patients [27–29]. Possible explanations for this phenomenon are hemoglobin may activate nuclear factor-kappa B transcription, inactivate nitric oxide to mediate vascular homeostasis and hemoglobin membranes, which can induce plaque instability and atherosclerosis progression [30–32]. According to Chen's report, gender difference affects arterial stiffness in healthy Chinese population [33]. However, we failed to demonstrate this relationship in our ESRD patients. This discrepancy may due to the different study population.
Limitation
We recognized several limitations to our analysis. The high arterial stiffness group comprised of more diabetes patients, which may confound intergroup comparisons. The categories and accumulated dosage of medications for mineral bone disease were absent. The body fat mass percentage measured before dialysis could be confounded by hypervolemic status. Moreover, the present study had a cross-sectional design and a small sample size from a single medical center. Thereby, it is beyond the scope of this study to examine the consequence of leptin on blood vessel in HD population. However, to the best of our knowledge, this study is the first one that reports a positive correlation between serum leptin level and central arterial stiffness in chronic HD patients.
Conclusion
In conclusion, our study demonstrated that hyperleptinemia was positively correlated to the high cfPWV and thus was related to high central arterial stiffness in HD patients. Besides, a positive correlation between hemoglobin and arterial stiffness also observed.
References
- 1. Blacher J, Guerin A, Pannier B, Marchais S, Safar M, London G. Impact of Aortic Stiffness on Survival in End-Stage Renal Disease. Circulation. 1999;99(18):2434–2439. pmid:10318666
- 2. Blacher J, Pannier B, Guerin A, Marchais S, Safar M, London G. Carotid Arterial Stiffness as a Predictor of Cardiovascular and All-Cause Mortality in End-Stage Renal Disease. Hypertension. 1998;32(3):570–574. pmid:9740628
- 3. Rahmouni K. Leptin-Induced Sympathetic Nerve Activation: Signaling Mechanisms and Cardiovascular Consequences in Obesity. Current Hypertension Reviews. 2010;6(2):104–109. pmid:21562617
- 4. Rahmouni K. Leptin-Induced Sympathetic Nerve Activation: Signaling Mechanisms and Cardiovascular Consequences in Obesity. Current Hypertension Reviews. 2010;6(2):104–109. pmid:21562617
- 5. Cheng K, Chu C, Lee K, Lin T, Hsieh C, Chiu C et al. Adipocytokines and proinflammatory mediators from abdominal and epicardial adipose tissue in patients with coronary artery disease. International Journal of Obesity. 2007;32(2):268–274. pmid:17878891
- 6. Qasim A, Mehta N, Tadesse M, Wolfe M, Rhodes T, Girman C et al. Adipokines, Insulin Resistance, and Coronary Artery Calcification. Journal of the American College of Cardiology. 2008;52(3):231–236. pmid:18617073
- 7. Wang J, Lee C, Chen M, Yang C, Chen Y, Hsu B. Association of Serum Osteoprotegerin Levels With Carotid-Femoral Pulse Wave Velocity in Hypertensive Patients. The Journal of Clinical Hypertension. 2014;16(4):301–308. pmid:24640954
- 8. Lee C, Wang J, Chen Y, Chen M, Yang C, Hsu B. Serum Osteopontin Level Correlates with Carotid-Femoral Pulse Wave Velocity in Geriatric Persons. BioMed Research International. 2014;2014:1–7.
- 9. Hsu B, Shih M, Chen Y, Ho G, Lin T, Lee M. High Serum Osteoprotegerin Is Associated with Arterial Stiffness in Kidney Transplant Patients. The Tohoku Journal of Experimental Medicine. 2015;236(4):247–253. pmid:26156285
- 10. Tsai J, Le M, Chen Y, Ho G, Shih M, Hsu B. Hyperleptinemia Is a Risk Factor for the Development of Central Arterial Stiffness in Kidney Transplant Patients. Transplantation Proceedings. 2015;47(6):1825–1830. pmid:26293058
- 11. 2013 ESH/ESC Guidelines for the management of arterial hypertension. Revista Española de Cardiología (English Edition). 2013;66(11):880.
- 12. Rider O, Tayal U, Francis J, Ali M, Robinson M, Byrne J et al. The Effect of Obesity and Weight Loss on Aortic Pulse Wave Velocity as Assessed by Magnetic Resonance Imaging. Obesity. 2010;18(12):2311–2316. pmid:20360756
- 13. Bełtowski J. Leptin and the regulation of endothelial function in physiological and pathological conditions. Clinical and Experimental Pharmacology and Physiology. 2012;39(2):168–178. pmid:21973116
- 14. Windham B, Griswold M, Farasat S, Ling S, Carlson O, Egan J et al. Influence of Leptin, Adiponectin, and Resistin on the Association Between Abdominal Adiposity and Arterial Stiffness. American Journal of Hypertension. 2010;23(5):501–507. pmid:20150891
- 15. Lee M, Chen Y, Ho G, Shih M, Chou K, Hsu B. Serum Leptin Levels Positively Correlate With Peripheral Arterial Stiffness in Kidney Transplantation Patients. Transplantation Proceedings. 2014;46(2):353–358. pmid:24655962
- 16. Tsai J, Wang J, Chen M, Yang C, Chen Y, Hsu B. Association of serum leptin levels with central arterial stiffness in coronary artery disease patients. BMC Cardiovascular Disorders. 2016;16(1).
- 17. Sharma K, Considine R, Michael B, Dunn S, Weisberg L, Kurnik B et al. Plasma leptin is partly cleared by the kidney and is elevated in hemodialysis patients. Kidney International. 1997;51(6):1980–1985. pmid:9186891
- 18. Dagogo-Jack S, Ovalle F, Landt M, Gearing B, Coyne D. Hyperleptinemia in patients with end-stage renal disease treated by continuous ambulatory peritoneal dialysis. Perit Dial Int. 1998;18:34–40. pmid:9527027
- 19. Sweeney G. Cardiovascular effects of leptin. Nature Reviews Cardiology. 2009;7(1):22–29. pmid:19949425
- 20. Nasrallah MZiyadeh F. Overview of the Physiology and Pathophysiology of Leptin With Special Emphasis on its Role in the Kidney. Seminars in Nephrology. 2013;33(1):54–65. pmid:23374894
- 21. Muhsen Hasan K. Comparative Study of Leptin and Phentolamine Effects on Cardiovascular System. Cardiovascular Pharmacology: Open Access. 2015;04(05).
- 22. Raikou V, Evagellatou A, Kyriaki D. The relationship between leptin and arterial stiffness in patients on dialysis. Journal of Molecular Pathophysiology. 2014;3(1):6.
- 23. Briet M, Boutouyrie P, Laurent S, London G. Arterial stiffness and pulse pressure in CKD and ESRD. Kidney International. 2012;82(4):388–400. pmid:22534962
- 24. Coppari R Bjørbæk C. Leptin revisited: its mechanism of action and potential for treating diabetes. Nature Reviews Drug Discovery. 2012;11(9):692–708. pmid:22935803
- 25. Schram M, Henry R, van Dijk R, Kostense P, Dekker J, Nijpels G et al. Increased Central Artery Stiffness in Impaired Glucose Metabolism and Type 2 Diabetes: The Hoorn Study. Hypertension. 2003;43(2):176–181. pmid:14698999
- 26. Metabolic parameters associated with arterial stiffness in older adults with Type 2 diabetes. Journal of Hypertension. 2013;31(7):1497.
- 27. Shimizu Y, Nakazato M, Sekita T, Kadota K, Yamasaki H, Takamura N et al. Association between hemoglobin levels and arterial stiffness for general Japanese population in relation to body mass index status: The Nagasaki Islands study. Geriatrics & Gerontology International. 2013;14(4):811–818.
- 28. Robles N, Escola J, Albarran L, Espada R. Correlation of Serum Magnesium and Serum Lipid Levels in Hemodialysis Patients. Nephron. 1997;78(1):118–119.
- 29. Hamid N. Association of serum leptin with anemia in maintenance hemodialysis patients. Saudi Journal of Kidney Diseases and Transplantation. 2006;17(4):521. pmid:17186687
- 30. Tziakas D, Chalikias G, Stakos D, Boudoulas H. The role of red blood cells in the progression and instability of atherosclerotic plaque. International Journal of Cardiology. 2010;142(1):2–7. pmid:19906450
- 31. Moreno P. Neovascularization in Human Atherosclerosis. Circulation. 2006;113(18):2245–2252. pmid:16684874
- 32. Kim-Shapiro D. Unraveling the Reactions of Nitric Oxide, Nitrite, and Hemoglobin in Physiology and Therapeutics. Arteriosclerosis, Thrombosis, and Vascular Biology. 2006;26(4):697–705. pmid:16424350
- 33. Chen K, Li P, Li YJ, Li T, Mu YM. Sex disparity in the association between hypertriglyceridemic waist phenotype and arterial stiffness in Chinese healthy subjects. Postgrad Med. 2016. 128(8): 783–789. pmid:27437733