Clin Exp Nephrol (2012) 16:629–635 DOI 10.1007/s10157-012-0610-x

ORIGINAL ARTICLE

A lower level of reduced albumin induces serious cardiovascular incidence among peritoneal dialysis patients Hiroyuki Terawaki • Yukie Matsuyama • Nanae Matsuo • Makoto Ogura Jun Mitome • Akihiko Hamaguchi • Tomoyoshi Terada • Seiichi Era • Tatsuo Hosoya

•

Received: 16 October 2011 / Accepted: 30 January 2012 / Published online: 23 February 2012 Ó Japanese Society of Nephrology 2012

Abstract Background Human serum albumin is composed of human mercaptoalbumin (HMA) with cysteine residues having reducing powers and of oxidized human non-mercaptoalbumin. Previously, we reported that a lower HMA level is closely related to serious cardiovascular disease (CVD) incidence and mortality among hemodialysis patients. However, the relationship between HMA level and CVD incidence among peritoneal dialysis (PD) patients is unclear. Methods We measured the redox state of human serum albumin using high-performance liquid chromatography in 30 continuous ambulatory PD patients. The association between HMA and incidental CVD events was evaluated. Results Eight patients experienced symptomatic CVD events (5 patients died) at the 5-year follow-up. The concentration and fraction of HMA (cHMA and f(HMA), respectively) showed significantly lower values in patients with CVD than those without CVD (cHMA 1.58 ± 0.39 and 2.16 ± 0.43 g/dL, f(HMA) 48.9 ± 5.4 and 56.4 ± 8.6%, respectively). Multiple forward stepwise regression analysis using cHMA and f(HMA) as the criterion variables H. Terawaki
N. Matsuo
M. Ogura
J. Mitome
A. Hamaguchi
T. Hosoya Division of Kidney and Hypertension, The Jikei University School of Medicine, Tokyo, Japan H. Terawaki (&) Division of Kidney and Hypertension, The Jikei University Kashiwa Hospital, 163-1 Kashiwa-shita, Kashiwa, Chiba 277-8567, Japan e-mail: [email protected] Y. Matsuyama
T. Terada
S. Era Division of Physiology and Biophysics, Gifu University Graduate School of Medicine, Gifu, Japan

was performed, and C-reactive protein and hemoglobin were adopted as significant explanatory variables in the former equation, whereas urea nitrogen was adopted in the latter equation. Multiple logistic regression analysis revealed that cHMA is a statistically, and f(HMA) is a marginally significant explanatory variable of CVD incidence (p = 0.0369, R = -0.260 and p = 0.0580, R = -0.214, respectively). Conclusions Lower HMA level, which might be caused by chronic inflammation, anemia and accumulation of dialyzable uremic toxin(s), is closely related to serious CVD incidence among PD patients. Keywords Cardiovascular disease
Peritoneal dialysis
Oxidative stress
Redox state of albumin

Introduction Mortality among end-stage renal disease (ESRD) patients is higher than among the general population. In Japan, the mortality rate of ESRD patients on regular renal replacement therapy is twice as high as that of the general population. The leading cause of mortality among ESRD patients is cardiovascular disease (CVD) such as heart failure, apoplexy, myocardial infarction and peripheral artery disease [1]. If the incidence of CVD among ESRD could be suppressed, then the prognosis for ESRD patients could be improved. However, the effective strategy to suppress CVD is not clear, because the reason why CVD is so common among ESRD patients is fully understood. Recently, we found that a lower serum level of reduced albumin strongly contributes to CVD incidence among ESRD patients on regular hemodialysis (HD) therapy [2].

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From the view point of the redox state of free cysteine residue at position 34 from the N-terminus, human serum albumin (HSA) is a mixture of human mercaptoalbumin (HMA) in which the mercapto group is reduced, human non-mercaptoalbumin (HNA-1) which is the disulfide bond formation reversibly oxidized by either cysteine or glutathion, and HNA-2 which is strongly oxidized and becomes sulfinic or sulfonic. Because approximately 80% of the total free thiol content in plasma is made up by the thiol group of albumin [3], it is thought that a decrease of reduced albumin or HMA could induce serious complications via insufficient reductive capacity. The aim of the present study is to prove that the lower serum level of reduced albumin (HMA) is a powerful independent risk factor for serious CVD incidence among ESRD patients on peritoneal dialysis (PD), in a similar way as patients on HD. We performed measurements of the redox state of HSA in 30 ESRD patients on PD, and compared them with incidence and mortality due to CVD. As a result, our study revealed a close relationship between the lower serum level of reduced albumin (HMA) and serious CVD incidence.

Methods The present study is a prospective, single center cohort study of 5 years follow-up. The study involved 30 PD patients— 15 males and 15 females aged between 39 and 86 (62 ± 12) years who attended the Jikei University Kashiwa Hospital. All patients were on standard continuous ambulatory PD (three to five times exchange daily) using acid/high-glucose degradation product (GDP) solutions or neutral/lowGDP glucose solutions as peritoneal dialysate (n = 12 and 18, respectively). Patients with apparent infection, bleeding, liver dysfunction, collagen disease, systemic vasculitis, or malignancies were not included in this study. Patients with a history of apparent myocardial infarction or stroke were also excluded. No patient had received antioxidant agents such as ascoribic acid or vitamin E. Local committee approved the study protocol and written informed consent was obtained from all participants. Blood samples for measurement of HSA (Cys-34)-redox were obtained: 2 mL was drawn from the serum obtained by centrifugation, and stored at -80°C until analysis. In addition, the following hematologic and biochemical tests were performed using standard laboratory techniques: hemoglobin, total protein, albumin, urea nitrogen, creatinine, uric acid, sodium, potassium, chloride, calcium, inorganic phosphorus, magnesium, transferrin saturation, b2-microglubulin, and C-reactive protein (CRP). Measurement of the albumin redox state was performed using the high-performance liquid chromatography

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(HPLC) method reported previously [4]. The HPLC system consisted of an AS-8010 autosampler (injection volume 2 lL specimen; Tosoh, Tokyo, Japan) and a CCPM double-plunger pump (Tosoh) in conjunction with a SC-8020 system controller (Tosoh). The chromatograph was obtained using a Finnigan UV6000LP photo diode alley detector (detection area 200–600 nm with 1-nm step; Thermo Electron, Waltham, MA, USA). A Shodex-Asahipak ES-502N 7C column [10 9 0.76 cm (inner diameter), dimethylaminoethyl-form for ion-exchange HPLC, column temperature 35 ± 0.5°C; Showa Denko, Tokyo, Japan] was used in this study. Elution was performed by linear gradient elution with ethanol concentrations (0–1 min, 0%; 1–50 min, 0 ? 10%; 50–55 min, 10 ? 0%; 55–60 min, 0%) for specimen in 0.05 M sodium acetate and 0.40 M sodium sulfate mixture (pH 4.85) at a flow rate of 1.0 mL/ min. Deaeration of the buffer solution was performed by bubbling helium. HPLC profiles obtained from these procedures were subjected to numerical curve-fitting using simulation software (PeakFit version 4.05; SPSS Science, Chicago, IL, USA), and each peak shape was approximated by a Gaussian function. From HPLC profiles of HSA obtained from these procedures, the value for each fraction of HMA, HNA-1, and HNA-2 to total HSA [f(HMA), f(HNA-1), f(HNA-2)] were calculated. Using these values and albumin concentration, the concentration for each fraction (cHMA, cHNA-1 and cHNA-2) were also calculated. Five years after the measurement of HSA-redox, the vital and CVD status of participants were established, and the relationship between CVD and HSA-redox was evaluated. In this study, CVD was defined as (1) acute myocardial infarction, (2) apoplexy, (3) peripheral artery disease accompanied with toe necrosis, or (4) sudden cardiac death (sudden death without signs of any other diseases such as apoplexy, gastrointestinal bleeding, acute infection or malignancies). We used the statistical software Stat View 5.0 (SAS Institute, Inc., Cary, NC, USA). Data are presented as mean ± SD, unless otherwise specified. Values were compared by unpaired t test or Chi-squared test, as appropriate. For the magnitude of the correlation, we used Pearson’s correlation coefficient (R). For all analyses, twotailed p \ 0.05 was considered statistically significant. The authors had full access to the data and take responsibility for its integrity.

Results A total of 8 patients experienced symptomatic CVD events at the 5-year follow-up—cerebral infarction (n = 5), peripheral artery disease (n = 2) or acute myocardial

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Table 1 Characteristics of respective groups

* p \ 0.05 versus CVD (-) group

CVD (?) (n = 8)

p value

Age (years)

59.7 ± 11.4

69.4 ± 11.6

0.0512

Gender (%male)

59.1

25.0

0.0986

Dialysis vintage (months)

41.4 ± 20.0

37.3 ± 17.4

0.6117

Primary disease (%diabetes)

13.6

50.0

0.0373*

Combination of weekly HD (%)

27.3

12.5

0.4171

Oliguric patients (%)

54.5

75.0

0.3287

Usage of acid/high-GDP solutions (%)

27.3

75.0

0.0183*

CVD (?) (n = 8)

p value

Table 2 Laboratory data of respective groups

CVD (-) (n = 22) Hemoglobin (g/dL)

9.86 ± 1.96

9.18 ± 1.05

0.3620

Alanine aminotransferase (IU/L)

13.9 ± 7.5

11.3 ± 5.8

0.3829

Total protein (g/dL)

6.49 ± 0.43

6.38 ± 0.91

0.6386

Urea nitrogen (mg/dL)

60.1 ± 16.1

57.8 ± 9.8

0.6986

Creatinine (mg/dL)

10.93 ± 2.88

8.89 ± 3.61

0.1195

Uric acid (mg/dL)

7.51 ± 1.56

7.24 ± 1.18

0.6586

Sodium (mEq/L) Potassium (mEq/L)

* p \ 0.05 versus CVD (-) group

CVD (-) (n = 22)

141.9 ± 3.2 4.47 ± 0.65

142.6 ± 4.5 4.01 ± 0.75

0.6332 0.1116

Chloride (mEq/L)

99.7 ± 4.4

99.9 ± 2.9

0.9091

Corrected calcium (mg/dL)

9.56 ± 0.65

9.38 ± 0.57

0.4761

Inorganic phosphorus (mg/dL) Magnesium (mg/dL)

5.40 ± 1.11 2.29 ± 0.41

6.11 ± 1.26 2.25 ± 0.64

0.1414 0.8373

b2-microglobulin (lg/dL)

30.96 ± 10.70

34.85 ± 11.76

0.3983

Transferrin saturation (%)

33.4 ± 15.0

21.7 ± 6.9

0.0445*

C-reactive protein (mg/dL)

0.20 ± 0.17

0.50 ± 0.65

0.0470*

infarction (n = 1). Among these patients, 5 subjects died within 1 month after the CVD event. Patients were then stratified into two groups—CVD (-) group (n = 22) or CVD (?) group (n = 8). Basic characteristics and laboratory data of the respective groups at the beginning of this study are shown in Tables 1 and 2, respectively. In the CVD (?) group, the percentage of diabetes, usage of acid/high-GDP solutions, and CRP were significantly higher, whereas transferrin saturation was significantly lower. Serum albumin and its redox state at the beginning of this study are shown in Table 3. With regard to the the redox state of HSA (Cys-34), the concentration of HMA (cHMA) was significantly lower in the CVD (?) group than in the CVD (-) group (1.58 ± 0.39 and 2.16 ± 0.43 g/dL, respectively, p = 0.0026), and the ratio of HMA (f(HMA)) was also significantly lower in the CVD (?) group than in the CVD (-) group (48.9 ± 5.4 and 56.4 ± 8.6%, respectively, p = 0.0278). With regard to the value of HNA-1, the ratio (f(HNA-1)) was significantly higher in

the CVD (?) group than in the CVD (-) group (40.5 ± 8.1 and 47.6 ± 5.2%, respectively, p = 0.0282), whereas such a difference was not observed in the comparison between concentration (cHNA-1) in the CVD (?) group and that in the CVD (-) group (1.52 ± 0.31 and 1.53 ± 0.29 g/dL, respectively, p = 0.9152). With regard to the value of HNA-2, neither the concentration (cHNA-2 0.12 ± 0.02 and 0.12 ± 0.03 g/dL, respectively, p = 0.8321) nor the ratio (f(HNA-2) 3.6 ± 0.4 and 3.1 ± 0.8%, respectively, p = 0.0872) showed a significant difference between the two groups. To evaluate the impact of HMA on CVD incidence, we then divided the subjects into two groups on the basis of cHMA and f(HMA) value: cHMA C2.0 versus \2.0 g/dL and f(HMA) C55 versus \55%, respectively. The relationship between CVD incidence and HMA value (cHMA and f(HMA)) is shown in Fig. 1. CVD incidence was significantly higher in the group with the higher HMA value. In order to know if there are any risk factors affecting the redox state of HSA, we performed simple and multiple

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Table 3 Serum albumin and its redox state

Total (n = 30)

CVD (-) (n = 22)

CVD (?) (n = 8)

p value

3.65 ± 0.52

3.81 ± 0.37

3.21 ± 0.64

0.0036**

Albumin (g/dL) Total cHMA

2.00 ± 0.49

2.16 ± 0.43

1.58 ± 0.39

0.0026**

cHNA-1

1.53 ± 0.29

1.53 ± 0.29

1.52 ± 0.31

0.9152

cHNA-2

0.12 ± 0.03

0.12 ± 0.03

0.12 ± 0.02

0.8321

f(HMA)

54.4 ± 8.5

56.4 ± 8.6

48.9 ± 5.4

0.0278*

f(HNA-1)

42.4 ± 8.0

40.5 ± 8.1

47.6 ± 5.2

0.0282*

f(HNA-2)

3.2 ± 0.7

3.1 ± 0.8

3.6 ± 0.4

0.0872

Redox state (%)

* p \ 0.05 and ** p \ 0.005 vs CVD (-) group

Fig. 1 The relationship between CVD incidence and HMA value. CVD incidence was significantly higher in lower HMA group, both in concentration (a cHMA) and in ratio (b f(HMA))

CVD, living (%) CVD, died (%)

A 50

B

40

17.6

50 40 17.6

30

30 p=0.0039

20

20

p=0.0399

29.4 10

10 p=0.0322 0

0 (n=13)

23.5

7.7 (n=17)

(n=13)

(n=17)

ƒ(HMA)

7.7 15.4 30.8

(stepwise forward) regression analysis, in which cHMA and f(HMA) were adopted as the criterion variables, whereas CRP, transferrin saturation, urea nitrogen, hemoglobin, age, primary disease (diabetes = 1), and usage of acid/high GDP solutions were the explanatory variables. Results are shown in Table 4. With regard to concentration (cHMA), CRP, transferrin saturation and age significantly correlated with cHMA in the simple regression analysis, whereas CRP and hemoglobin were selected as significant explanatory variables in the multiple regression analysis. With regard to fraction (f(HMA)), only UN significantly correlated with f(HMA) in the simple regression analysis, and likewise, only UN was selected as significant explanatory variable in the multiple regression analysis. Finally, we performed multiple logistic regression analysis in which CRP, hemoglobin, UN and cHMA (Model A) or f(HMA) (Model B) were determined to be the explanatory variables, whereas CVD incidence was the criterion variable. Results are shown in Table 5. Of these explanatory variables, only cHMA exhibited statistical significance in Model A (p = 0.0369, R = -0.260), whereas f(HMA) showed marginal significance in Model B (p = 0.0580, R = -0.214).

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N. S. (p=0.2487)

0

cHMA

%elderly (age %diabetes %acidic solution

0

35.3 29.4 47.1

(p-value) 0.0813 0.3855 0.3842

7.7 7.7 23.1

35.3 35.3 52.9

(p-value) 0.0813 0.0813 0.1047

Discussion In this study, we showed that a lower level of reduced albumin is a powerful independent risk factor for serious CVD incidence among PD patients. From the view point of redox state of HSA, HSA is composed of HMA (reduced form) and HNA (oxidized form). Furthermore, HNA consists of HNA-1 (a major fraction, reversibly oxidized form) and HNA-2 (a minor fraction, irreversibly oxidized form). We have developed a convenient HPLC system for the clear separation of HSA into HMA and HNA [5, 6], and we have extensively studied the dynamic changes of HSA (Cys-34)-redox state under various physiologic [7–9] and pathophysiologic states, such as hepatic [10, 11], renal [2, 4, 12–14], diabetic [15], and other diseases [16–18]. The present study provides several lines of evidence to suggest that a lower HMA value powerfully influences the incidence and mortality of CVD. Formerly, the redox state of small-molecule thiols (glutathione and free cysteine) in plasma was reported to be the predictor for the presence of early athelosclerosis [19] and endothelial dysfunction [20]. Theoretically, the redox state of small-molecule thiols

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Table 4 Correlation between cHMA, f(HMA) and clinical data cHMA

f (HMA)

Simple R C-reactive protein Transferrin saturation Urea nitrogen Creatinine

-0.522 0.403 -0.271 0.101

Multiple

Simple

Multiple

p value

R

p value

R

0.0026**

-0.528

0.0024**

-0.275

0.1417

0.205

0.2804

0.0264* 0.1480 0.5975

p value

-0.410 -0.139

0.0236* 0.4633

Uric acid

-0.133

0.4874

-0.260

0.1666

Beta 2-microgloblin

-0.186

0.3276

-0.259

0.1691

0.357

0.0523

0.331

0.0743

Hemoglobin

0.365

0.0206*

Age

-0.439

0.0145*

-0.323

0.0815

Primary disease (diabetes = 1)

-0.313

0.0922

-0.245

0.1938

Usage of acid/high-GDP solutions

-0.146

0.4459

-0.312

0.0935

R

p value

-0.410

0.0236*

*p \ 0.05 and **p \ 0.005

Table 5 Result of multiple logistic regression analysis in which CVD incidence was adapted as criterion variable

*p \ 0.05

Model A v

2

Model B R

p value

v2

R

p value

Constant

3.252

0.190

0.0713

3.202

0.186

0.0735

C-reactive protein

0.002

0.000

0.9616

0.666

0.000

0.4143

Hemoglobin

0.019

0.000

0.8902

0.182

0.000

0.6696

Urea nitrogen cHMA

1.829 4.357

0.000 -0.260

0.1762 0.0369*

1.969

0.000

0.1605

3.594

-0.214

0.0580

f(HMA)

depends mainly on that of HSA, because a large portion of the thiol groups in human extracellular fluid is primarily derived from HMA, as mentioned above. In this context, an insufficiency of HMA might lead to CVD events via subclinical atherosclerosis and endothelial dysfunction. In the present study, higher CRP and lower hemoglobin were selected as dependent contributors of lower HMA concentration (cHMA), whereas higher UN was selected as a dependent contributor of lower HMA ratio (f(HMA)). From these findings, chronic inflammation, anemia, and accumulation of some dialyzable uremic toxin(s) might be regarded as potential causable factors of the decrease of HMA. Chronic inflammation is common in CKD patients and is reported to be induced, at least in part, by micro-endotoxemia in CKD patients before dialysis [21], on HD [22], and on PD [23]. In the inflammatory state, hepatic cells mainly synthesize CRP instead of unmodified albumin = HMA. Therefore, it is reasonable that chronic inflammation reduces HMA value via suppression of synthesis, as in the case of liver cirrhosis [11]. Anemia is also common in CKD patients. It is reported that anemia is related to elevation of the level of

malonyldialdehyde (the marker of lipid peroxidation by radicals) in CKD patients on hemodialysis [24]. Considering that radical generation from neutrophils is accelerated in CKD patients [25], and that the liver uptake clearance of ‘oxidized’ albumin is reported to be increased by 11-fold [26], anemia might reduce HMA value via oxidation. With regard to the relationship between dialyzable uremic toxin(s) and decrease of HMA, we previously reported this relationship in the clinical setting such as predialysis [12], HD [2] and PD patients [13]. Recently, we found from cell culture experiments that aortic endothelial cells actively generate the thiol-disulfide exchange reaction, i.e., the HNA-1 ? HMA conversion of human albumin [27], while such a reaction is suppressed by methylglyoxal [28], one of the representative dialyzable uremic toxins [29]. Therefore, theoretically, it is supposed that accumulation of dialyzable uremic toxins, such as methylglyoxal, reduces HMA value via suppression of HSA reduction by the endothelial cells of whole blood vessels. With regard to the reason why the risk factors for low cHMA (inflammation and anemia) and for low f(HMA) (high UN) were different in this study, we suspect that such

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a difference reflects the difference of mechanism of lowering HMA; the decline of cHMA might reflect accelerated oxidation of HMA, whereas the decline of f(HMA) might reflect impaired reductive potential of the body for HNA. The present study revealed that a lower level of HMA (both cHMA and f(HMA)) is correlated with future occurrence of CVD. At present, it is unclear whether low HMA is (one of) a cause of CVD occurrence, or only a surrogate of bad condition. However, we suspect that low HMA is really a cause of CVD occurrence, because HMA acts in the body as the strongest extracellular antioxidant [3], and because cHNA (oxidized or impaired albumin) was not increased in CVD patients as shown in Table 3. This concern should be proved by a future interventional approach to increase HMA level [30]. There are some important limitations in this study. Firstly, the cohort size is too small to estimate accurate degree of risk caused by HSA (Cys-34)-oxidation. Secondary, the present study was a single center study. Thus, further study based on a larger size multi-center cohort is an issue to be clarified in the future. Conflict of interest

None.

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