Table of Contents  
ORIGINAL ARTICLE
Year : 2019  |  Volume : 13  |  Issue : 4  |  Page : 563-569

Study of serum cystatin C levels in patients with obstructive sleep apnea


1 Department of Chest Department, Faculty of Medicine, Tanta University, Egypt
2 Clinical Pathology Department, Faculty of Medicine, Tanta University, Egypt

Date of Submission09-Apr-2019
Date of Decision14-Aug-2019
Date of Acceptance16-Aug-2019
Date of Web Publication25-Oct-2019

Correspondence Address:
Salwa Ganna
Chest Department, Faculty of Medicine, Tanta University, 31527
Egypt
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Source of Support: None, Conflict of Interest: None


DOI: 10.4103/ejb.ejb_31_19

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  Abstract 

Background Serum cystatin C is a sensitive indicator for early renal impairment in patients with obstructive sleep apnea (OSA). In patients with OSA without known chronic kidney disease (CKD), serum cystatin C was found to be elevated, indicating latent renal disease, which may be caused by recurrent episodes of hypoxemia and reoxygenation that trigger inflammatory process.
Objective To evaluate serum levels of cystatin C in otherwise healthy patients with OSA to predict the future risk of latent renal impairment in these patients.
Patients and methods A total of 30 patients were classified into two groups: group I included 10 healthy controls, and group II included 20 patients with OSA. The following were done: full history taking, clinical examination, pulmonary function tests, subjective evaluation of daytime sleepiness using the Epworth Sleepiness Scale, and overnight polysomnography. Finally, serum cystatin C levels at the end of polysomnography and glomerular filtration rate was calculated using modification of diet in renal disease formula and CKD-Epidemiology Collaboration cystatin equation.
Results In patients with OSA, the mean level of serum cystatin C was statistically significantly higher than that in controls. These higher levels were sex, age, and BMI independently. Moreover, serum levels of cystatin C in patients with OSA were significantly correlated with OSA severity (apnea-hypopnea index) and degree of nocturnal hypoxia through positive correlation with total sleep time less than 90%, total sleep time less than 80%, and respiratory disturbance index and negative correlation with average SPO2%, lowest SPO2%, and estimated glomerular filtration rate by CKD-Epidemiology Collaboration cystatin equation.
Conclusions Higher serum levels of cystatin C were detected in patients with OSA without known comorbidities, which indicates that these patients are at a higher risk of developing CKD. Intermittent hypoxia seems to have the main role in the progression of this process.

Keywords: chronic kidney disease, chronic kidney disease cystatin C, obstructive sleep apnea


How to cite this article:
Elfeky E, Abd El-Zaher A, Elbendary A, Ganna S. Study of serum cystatin C levels in patients with obstructive sleep apnea. Egypt J Bronchol 2019;13:563-9

How to cite this URL:
Elfeky E, Abd El-Zaher A, Elbendary A, Ganna S. Study of serum cystatin C levels in patients with obstructive sleep apnea. Egypt J Bronchol [serial online] 2019 [cited 2024 Mar 28];13:563-9. Available from: http://www.ejbronchology.eg.net/text.asp?2019/13/4/563/269681


  Introduction Top


Obstructive sleep apnea (OSA) is characterized by recurrent attacks of either partial or complete upper airway collapse, resulting in hypopnea or apnea during sleep [1]. Several studies reported that chronic kidney disease (CKD) prevalence increases in patients with OSA, which is a known risk factor for cardiovascular disease (CVD), even in mild OSA [2],[3]. Cystatin C, a protein with a low molecular weight, is an inhibitor of lysosomal cysteine protease. It is mainly used as a biomarker for kidney function, as cystatin C is filtered by glomeruli and then reabsorbed and catabolized in the proximal convoluted tubules, but it is not secreted by the tubules [4]. In contrast to serum creatinine, cystatin C is not influenced by either muscle mass, age, or sex. So, it is a more sensitive indicator of mild and early kidney impairment and is a faster and a better estimate of glomerular filtration rate (GFR) than serum creatinine [5]. This work aimed at evaluation of serum levels of cystatin C in otherwise healthy patients with OSA to predict the future risk of latent renal impairment in these patients.


  Patients and methods Top


This prospective analytic observational cross sectional study was conducted in the Sleep Laboratory Unit in Chest Department, Tanta University Hospitals, between July 2017 and February 2018. A total of 101 patients were evaluated for OSA; 42 patients were hypertensive, 29 were diabetic, 21 patients were cardiac, and nine patients had CKD. So, these 71 patients were excluded from the study, and only 30 patients were included. The local ethics committee of our center has approved the research protocol, and written informed consents were obtained from all participants.

The 30 patients were classified into two groups: group I included 10 healthy controls, matched to patients with OSA by sex, age, and BMI. All control persons are apparently healthy individuals with no history of any diseases, had normal physical examinations, and had apnea-hypopnea index (AHI) less than 5 event/h. Group II included 20 patients with OSA as confirmed by AHI more than or equal to 5 event/h. Patients were diagnosed with OSA if their AHI ranges from 5 events/h to less than 15 event/h and presented at least one of the following: loud snoring, daytime sleeping, fatigue, and breathing interruption during sleep [6]. Patients with AHI more than or equal to 15 events/h were diagnosed with OSA regardless of whether they had any additional compliant [6]. OSA was considered mild if AHI ranges from 5 events/h to less than 15 events/h, moderate if AHI ranges from 15 events/h to less than 30, and severe if AHI more than or equal to 30 events/h. If AHI less than 5 events/h, the person was taken as healthy control. Patients with central sleep apnea diagnosed by polysomnography (PSG), patients with systemic hypertension, diabetic patients, previously diagnosed patients with OSA, patients who started treatment with either CPAP or oral appliances, patients with cardiac or hepatic diseases, and patients with known renal diseases were excluded from this study.

All 30 persons were subjected to the following:
  1. History taking, including personal history; medical history; and subjective evaluation of daytime sleepiness using the Epworth Sleepiness Scale, which is a short questionnaire aiming at evaluation of the possibility of falling asleep in different situations [7].
  2. Physical examination, which included measurement of height; weight; neck, hip, and waist circumferences; and waist/hip circumference ratio. BMI was calculated using the following formula: BMI = weight (kg)/height2 (m).
  3. Arterial blood gas analysis.
  4. Plain chest x-ray (posteroanterior view)
  5. ECG.
  6. Pulmonary function testing.
  7. Overnight PSG was conducted in the Sleep Laboratory Unit in Chest Department, Tanta University Hospitals, at night during sleep for at least 6 h (started at 10 pm). Participants were connected to SOMNO screen™ plus PSG+ (SOMNO Medics GmbH, Germany), which included the following channels: pressure and flow (cannula and thermistor), snore (cannula and/or microphone), thoracic effort, abdominal effort, pulse oximetry, ECG, periodic leg movement, electrooculogram, electroencephalogram (10 electrodes) to detect total sleep time (TST), and sleep efficiency. Respiratory event analysis included AHI and respiratory disturbance index (RDI). It identified different types of apneas (obstructive, central, or mixed) and calculated their absolute values and indices. It estimated respiratory effort related arousal index and absolute value. It measured the snoring and arousal index. Oxygen saturation analysis determined the baseline, average, and minimal oxygen saturation. It estimated TST less than 90% (time of sleep with oxygen saturation below 90%) and TST less than 80%, as well as oxygen desaturation index which is the number of times per hour of sleep that the blood’s oxygen level drops by 3% or more from baseline. Heart rate analysis measured maximal, minimal, and average heart rate. The PSG analysis was done automatically for all participants by DOMNO software and then revised manually. Sleep stage and respiratory event scoring was done according to the standard criteria of the American Academy of Sleep Medicine (AASM), version 2.3 [8].
  8. Laboratory investigations: fasting venous blood samples were collected under complete aseptic conditions the morning after the study. Samples were divided correspondingly for the following:
    1. Routine laboratory investigations: fasting blood glucose considering diabetic range starting from 126 mg/dl [9], triglyceride, total cholesterol, urea, creatinine, and C-reactive protein.
    2. Cystatin C serum concentration: 2 ml of the venous sample is used after centrifugation within 1 h of collection. Serum samples were stored at −25°C for cystatin C analysis at the end of the study. Cystatin C was measured by using a particle-enhanced turbidimetric immunoassay.
  9. Estimated glomerular filtration rate (eGFR) was measured by modification of diet in renal disease (MDRD) formula [10] and the CKD-Epidemiology Collaboration (EPI) cystatin C equation [11] adjusted for age, sex, and race.


Statistical analysis

Expression of quantitative data as mean±SD was done. Data were tested for normal distribution using Kruskal–Wallis test and Mann–Whitney test to evaluate the significance of difference among both groups using SPSS, version 20 (Statistical Package for Social Sciences, version 20, IBM). A P value less than 0.05 was considered to be statistically significant. In addition, Pearson correlations were performed between serum cystatin C levels and different variables.


  Results Top


This study included 30 patients: 20 were diagnosed as have OSA by PSG (AHI≥5 event/h), and 10 apparent healthy control persons.

Demographic and anthropometric characteristics of both patients with OSA and controls are shown in [Table 1]. No statistically significant difference was detected between both groups regarding age, sex, percent of smokers, and BMI.
Table 1 Comparison of anthropometric characteristics between obstructive sleep apnea patients and controls

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Statistical comparison between the two studied groups regarding different PSG parameters is shown in [Table 2]. There was no statistically significant difference between both groups regarding TST and baseline SPO2, whereas average SPO2% and minimal SPO2% were found to be statistically significant lower in OSA group than in control group, with P value of 0.001 for all parameters. TST less than 90%, TST less than 80%, RDI, snoring index, and arousal index were found to be statistically significant higher in OSA group than in control group, with P value of 0.001 for all parameters, except arousal index, with P value of 0.028.
Table 2 Statistical comparison between the two studied groups as regard different polysomnographic parameters

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Regarding classification of OSA severity regarding AHI ([Figure 1]), OSA was mild in four patients, moderate in four patients, and severe in 12 patients. AHI ranged from 7.0 to 99.3 event/h, with mean±SD of 48.94±29.90 event/h.
Figure 1 Classification of OSA severity as regard apnea-hypopnea index (AHI) showed that OSA was mild in four (20%) patients, moderate in four (20%) patients and severe in 12 (60%) patients. OSA, obstructive sleep apnea.

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Statistical comparison between the two studied groups regarding different laboratory investigation is shown in [Table 3]. No significant differences were detected between both groups regarding ABG, fasting blood glucose, triglyceride, total cholesterol, blood urea, serum creatinine, and eGFR by MDRD formula. However, eGFR by CKD-EPI cystatin C equation was found to be statistically significant lower in OSA patients than control group. Moreover, serum cystatin C levels were statistically significant higher in OSA group than control group.
Table 3 Statistical comparison between the two studied groups regarding different laboratory investigations

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Receiver operating characteristic curve analysis ([Table 4], [Figure 2]) showed that cutoff value of eGFR by CKD-EPI equation in predicting renal injury was 60 ml min 1.73 m2, with a sensitivity of 95%, specificity of 100%, positive predictive value of 100%, negative predictive value of 91%, and accuracy of 97%.
Table 4 Receiver operating characteristic curve of estimated glomerular filtration rate by chronic kidney disease-Epidemiology Collaboration cystatin C equation

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Figure 2 Receiver operating characteristic (ROC) curve analysis showed that cutoff value of eGFR by CKD-EPI equation in predicting renal injury was 60 ml min 1.73 m2 with a sensitivity of 95%, specificity 100%, PPV 100%, NPV 91% and accuracy 97%. CKD, chronic kidney disease; eGFR, estimated glomerular filtration rate; EPI, Epidemiology Collaboration; NPV, negative predictive value; PPV, positive predictive value.

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Statistical correlation between serum levels of cystatin C and some studied parameters in patients with OSA is shown in [Table 5]. The OSA group revealed that there was no statistically significant correlation between serum cystatin C levels and either anthropometric parameters, age, baseline O2 saturation, serum creatinine, or eGFR by MDRD formula. A significant positive correlation was detected between serum cystatin C level and AHI, TST less than 90%, and TST less than 80%. There was a significant negative correlation between serum cystatin C and average SPO2%, minimal SPO2%, and eGFR by CKD-EPI equation.
Table 5 Statistical correlation between serum levels of cystatin C and some studied parameters in obstructive sleep apnea patients

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  Discussion Top


In this work, there was a statistically significant increase in serum cystatin C levels in OSA group than in control one. The key feature in OSA is intermittent hypoxia which appeared to have the main role in the pathological mechanism of CKD development in patients with OSA. This was proved by the significant positive correlation between cystatin C level and AHI, TST less than 90%, TST less than 80%, and RDI. However, there was a significant negative correlation between cystatin C and average SPO2%, minimal SPO2%, and eGFR by CKD-EPI cystatin C equation.

In a previous study by Kato et al. [12], they found that serum cystatin C levels were increased in patients with severe OSA without CKD, and they considered the serum cystatin C as a biomarker for both clinically latent renal disease and cardiovascular risk, which is an expected complication of OSA.

Zhang et al. [13] showed in across-sectional study that serum cystatin C levels were relatively higher in younger men with severe OSA and in younger men without known CKD and CVD. Moreover, they found that serum levels of cystatin C were correlated with oxygen desaturation index, high sensitivity C-reactive protein, serum creatinine, and eGFR. In addition, AHI was positively correlated with serum levels of cystatin C. Serum levels of cystatin C were significantly and negatively correlated with eGFR.

A study done by Archontogeorgis et al. [14] showed that higher serum levels of serum cystatin C were detected in middle-aged otherwise healthy patients with OSA compared with nonapneic who were matched for age and BMI, indicating that these patients are more susceptible to develop chronic kidney and CVD, and serum cystatin C levels were positively correlated with RDI, TST less than 90%, and average SPO2% during sleep. Another study done by Chuang et al. [15] concluded that albuminuria and serum cystatin C levels were positively correlated with OSA severity. Moreover, Chung et al. [16], in a study conducted on 433 patients with OSA of different severity and 54 healthy controls, found that serum cystatin C levels in the moderate OSA group and the extremely severe OSA group were higher compared with the control group and the eGFR levels were significantly lower in the moderate and extremely severe OSA group than that in the control group.

In the present work, there was no statistically significant difference in both groups regarding eGFR by MDRD formula, whereas on comparing the mean value of eGFR by CKD-EPI cystatin C equation between the two groups, it was found to be statistically significant lower in patients with OSA than control group.

The present study depends upon CKD-EPI-cys equation but not CKD-EPIcreat-cys equation, as there is no difference in reclassification between the two equations according to KDIGO guidelines [17].

A study of Chou et al. [18] showed that high prevalence of CKD is present in patients with severe OSA without hypertension or diabetes. Significantly positive correlations were found between severity of OSA and renal function impairment.

Matsushita et al. [19] found that although CKD-EPI cystatin equation detected fewer individuals as having CKD, it was more accurate in categorization of the risk for mortality and the development of ESRD than the MDRD study equation across a great number of participants.

Shlipak et al. [20] found that eGFR based on cystatin C alone or in combination with creatinine strengthens the association between the eGFR and the risks of death and end-stage renal disease across diverse populations more than eGFR based on creatinine.

These findings are in partial discrepancy with data from a cohort study by Rogacev et al. [21], where application of CKD-EPIcreat-cys, compared with the MDRD and CKD-EPIcreat equations, allows better prediction of CKD progression and death among patients with CKD. In a study of Zalucky et al. [22], it was found that OSA and nocturnal hypoxemia are closely related to CKD and up-regulation of the renin–angiotensin system, which is deleterious to renal function.

Doğaner et al. [23] believed that the eGFR by CKD-EPI-cys C equation or the combined equation with creatinine has superiority to GFR equations based on creatinine alone.

Uyar et al. [24] showed that renal dysfunction seen in patients with OSA could be regarded as an additive or even synergistic result of both direct effects of disordered sleep itself and indirect effect by way of metabolic derangements.

In contrast to the recent study, Shardlow et al. [25] did not recommend the use of cystatin C for routine diagnosis of CKD, and they recommended its use only in conditions where the use of serum creatinine is known to be unreliable. Moreover, they concluded that the use of cystatin C did not improve the prediction of the risk for mortality or deterioration of CKD. The difference between their observation and ours can be explained by the differences in the aim of both studies, as they used cystatin C as a marker for detection of the severity of CKD in already diagnosed cases, but in the present study, the aim was to use cystatin C in early detection of renal impairment in apparently healthy individuals, in addition to the big difference in the number of targeted populations in both studies.

In the present study, eGFR by MDRD formula in all participants was not significantly affected because it depends mainly on creatinine level, which was not also significantly affected, as participants had not yet developed CKD, in contrast to eGFR by CKD-EPI cystatin equation, where it was statistically significant lower in patients with OSA than control group, as it depends mainly on cystatin C levels, which were statistically significant higher in patients with OSA, and it is a predictor of early and latent renal dysfunction.

Our study had several limitations: limited number of the study population and limited time of the study. Moreover, it is a case-controlled study, so follow-up is needed to determine the probable future prevalence of chronic renal disease in patients with OSA with high serum cyst C levels. Moreover, there is a probability that this study included patients having CKD despite their normal eGFR because proteins and albumin in urine had not been measured. Most of participants who were included in this analysis were elderly and had high prevalence of major chronic diseases, which were associated with a higher risk of CKD.

In conclusion, detection of higher levels of serum cystatin C in otherwise healthy patients with OSA could indicate an increased future risk of developing CKD in these patients. Intermittent hypoxia seems to play a central role in the progression of this process.

Financial support and sponsorship

Nil.

Conflicts of interest

There are no conflicts of interest.

 
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