Background
Cardiovascular disease (CVD) is a main cause of morbidity and mortality of end-stage renal disease (ESRD) patients [
1] and the risk of CVD is predicted by coronary artery calcification (CAC) independently in ESRD patients [
2,
3]. Thus, CAC can be an independent risk factor of CVD beyond conventional risk factors [
4,
5]. In ESRD patients, chronic kidney disease (CKD) - mineral and bone disorders (CKD-MBD) is a major complication. Decreased bone mineral density (BMD) associates with increased fracture risk and predicts higher mortality and cardiovascular events in CKD patients and the general population [
6‐
8]. Low BMD is associated with higher risk of CVD [
6,
9,
10].
Bone mineralization and vascular calcification share some common pathways [
11,
12]. An association of reduced BMD with vascular calcification has been found in the general population [
13,
14] as well as in ESRD patients [
15,
16]. However, no such association was found in some other studies in the general population [
17‐
20] and ESRD patients [
21]. Decreased cortical bone density has been found to associate with CAC [
22], and progression of CAC was predicted by osteoporosis [
23] in dialysis patients. Several molecular mechanisms have been suggested for the link between bone metabolism and vascular calcification [
24].
Since it is not clear to what extent a decreased BMD may be linked to increased risk of CAC and other manifestations in ESRD patients, we investigated sex-specific associations between total body BMD (tBMD) and BMD of different skeletal sub-regions, determined by dual-energy X-ray absorptiometry (DXA), and CAC, determined by computed tomography (CT) of the heart.
Methods
Patients
One hundred seventy-four ESRD patients with median age of 57 (10th–90th percentiles 29–75) years, 63% males were enlisted at the Department of Renal Medicine at Karolinska University Hospital at Huddinge, Stockholm, between March 2008 and June 2015. All patients from three different cohorts, who had undergone both coronary CT and DXA measurements, were included, 69 (40%) were incident dialysis patients, 67 (38%) prevalent peritoneal dialysis (PD) patients and 38 (22%) recipients of living donor kidney transplant (LD-Rtx). The Ethics Committee of Karolinska University Hospital Huddinge approved the study protocols. Informed consent in written was obtained from all patients. Baseline characteristics of the 174 included ESRD patients are outlined in Table
1.
Table 1
Clinical and biochemical characteristics for the total 174 ESRD patients and for two subgroups based according to CAC score
Demography and metabolic biomarkers |
Age, years | 57 (29, 75) | 41 (23, 63) | 64 (49, 78) | < 0.001 |
Male, % | 63 | 57 | 67 | 0.173 |
Diabetes, % | 28 | 10 | 40 | < 0.001 |
CVD, % | 22 | 3 | 36 | < 0.001 |
Body mass index, kg/m2 | 24.8 (19.9, 30.8) | 23.9 (19.7, 30.7) | 25.2 (20.7, 30.8) | 0.080 |
Systolic BP, mmHg | 139 (114, 169) | 135 (114, 163) | 143 (113, 179) | 0.024 |
Diastolic BP, mmHg | 83 (67, 97) | 85 (70, 100) | 81 (66, 96) | 0.123 |
Hemoglobin, g/L | 114 (94, 130) | 113 (92, 128) | 114 (100, 130) | 0.064 |
Triglycerides, mmol/L | 1.6 (0.9, 3.0) | 1.6 (0.9, 2.8) | 1.4 (0.9, 3.6) | 0.039 |
Cholesterol, mmol/L | 4.7 (3.3, 6.6) | 4.6 (3.4, 6.1) | 4.6 (3.0, 5.7) | 0.175 |
HDL-cholesterol, mmol/L | 1.2 (0.8, 2.3) | 1.4 (0.9, 2.4) | 1.1 (0.9, 2.3) | 0.373 |
Creatinine, μmol/L | 727 (491, 1012) | 738 (509, 1185) | 729 (414, 981) | 0.014 |
S-albumin, g/L | 33 (26, 39) | 35 (28, 40) | 32 (23, 38) | 0.001 |
hsCRP, mg/L | 2.1 (0.4, 18.7) | 1.2 (0.2, 9.1) | 3.6 (0.8, 35.4) | 0.003 |
TNF, pg/ml a | 15.3 (9.9, 20.4) | 12.9 (8.0, 19.8) | 16.7 (12.0, 20.7) | 0.003 |
IL-6, pg/ml b | 4.5 (0.9, 14.9) | 2.1 (0.4, 8.1) | 6.9 (2.2, 20.5) | < 0.001 |
PTX3 ng/mL c | 1.7 (0.7, 6.2) | 1.8 (0.6, 7.1) | 1.7 (0.7, 7.1) | 0.758 |
Total testosterone in male, nmol/Ld | 11.0 (5.8, 20.5) | 12.2 (7.4, 25.6) | 10.2 (4.7, 16.9) | 0.025 |
Mineral bone disease biomarkers |
iPTH, ng/L | 300 (96, 655) | 265 (113, 658) | 320 (79, 735) | 0.595 |
Calcium, mmol/L | 2.3 (2.0, 2.5) | 2.3 (2.1, 2.5) | 2.2 (1.9, 2.6) | 0.924 |
Phosphate, mmol/L | 1.8 (1.2, 2.5) | 1.9 (1.2, 2.4) | 1.8 (1.2, 2.6) | 0.559 |
1,25-OH vitamin D, nmol/L e | 13 (9, 28) | 16.5 (9, 34) | 11 (9, 23) | 0.054 |
25-OH vitamin D, ng/L f | 29 (13, 70) | 33 (14, 57) | 29 (14, 80) | 0.861 |
tBMD, g/cm2 | 1.12 (0.92, 1.30) | 1.13 (1.00, 1.31) | 1.10 (0.91, 1.27) | 0.095 |
T-score of tBMD | −0.8 (−2.7, 1.1) | − 0.6 (− 2.0, 1.2) | −1.1 (− 3.1, 1.1) | 0.006 |
Z-score of tBMD | − 0.4 (− 1.8, 1.2) | − 0.1 (− 1.5, 1.1) | − 0.5 (− 2.4, 1.3) | 0.097 |
Measurements of BMD
BMD was measured by dual-energy X-ray absorptiometry (DXA) [
25] and was presented in g/cm
2 or T-score (i.e. the number of standard deviations difference in BMD compared to young adults of the same gender) or Z-score (indicating the number of standard deviations difference in BMD compared to an age-matched reference population of the same gender)). DXA was performed in all 174 patients using a DPX-L device (GE Lunar iDXA with software enCore 2008 version 12, 30, 008, GE Medical systems, Chalfont St. Giles, UK). BMD of total body (tBMD) and several skeletal sub-regions were also obtained: head, arms, legs, trunk, ribs, spine and pelvis.
Measurements of CAC
CAC was measured by CT, a non-invasive approach, performed on a 64-channel detector scanner (LightSpeed VCT; General Electric (GE) Healthcare, Milwaukee, WI, USA) in cine mode. CAC was quantified in Agatston units (AUs) as a lesion with an area > 1 mm
2 and a peak intensity > 130 Hounsfield Units (HUs) based on the Agatston method previously described in detail [
26]. Details of CAC scan ascertainment and quantification have been published [
27‐
29] in our previous study. In this study, we used a CAC score > 100 AUs which was associated with an higer risk of myocardial ischaemia and cardiac events [
30] to identify patients with definite to extensive plaque burden.
Laboratory analysis and other measurements
Plasma blood samples were received after an overnight fast in the morning in the ESRD patients. If not analysed immediately, the samples were kept frozen at − 70 °C. Plasma tumour necrosis factor (TNF), interleukin-6 (IL-6) and total testosterone concentrations were tested by commercial kits according to the instructions of the manufacturer available for an Immulite Automatic Analyzer (Siemens Medical Solutions, Los Angeles, CA, USA). Pentraxin-3 (PTX3) was tested by ELISA kits of R&D systems (Abingdon, UK). The level of haemoglobin, serum creatinine, triglycerides, cholesterol, and high density lipoprotein (HDL)-cholesterol, calcium, phosphorus, intact parathyroid hormone (iPTH), 25(OH) and 1,25(OH)2 vitamin D3, and high-sensitivity C-reactive protein (hsCRP) were tested by routine methods at the Department of Laboratory Medicine, Karolinska University Hospital, Huddinge, Sweden.
At the baseline body mass index (BMI) was recorded according to height and body weight. Arterial systolic and diastolic blood pressures (BP) were measured three times after a 15-min resting period in the morning. Earlier or present occurrence of documented of cerebrovascular, cardiovascular, or peripheral vascular disease like patients had suffered from cerebrovascular disease (stroke), myocardial infarctions, clinical signs of ischemic heart disease (angina pectoris), peripheral ischemic atherosclerotic vascular disease, had a history of an aortic aneurysm, mitral stenosis, and cardiac failure, considered as signs of CVD and details of CVD event determination have been published [
31].
Statistical analysis
Data are presented as median (range of 10th to 90th percentile) or percentage, as appropriate. Comparisons between two groups were assessed by the non-parametric Wilcoxon test for continuous variables and Fischer’s exact test for categorical variables. Spearman rank correlation analysis was used to determine associations between selected parameters. A receiver operating characteristics (ROC) curve was plotted for T-score of tBMD, age and hsCRP in relation to presence of high CAC score (>100 AUs). To study the associations between BMD, CAC score and other parameters, a multivariable generalized linear model (GLM) analysis were performed. In GLM analysis (stratified by gender), age, diabetes and hsCRP were included in the model. Statistical analyses were performed using statistical software SAS version 9.4 (SAS Campus Drive, Cary, NC, USA). Statistical significance was set at the level of p < 0.05.
Discussion
To the best of our knowledge, this is the first study investigating how sex affects the associations of BMD of different skeletal sub-regions with CAC score in ESRD. Our main observation is that lower tBMD and lower BMD of skeletal sub-regions, in particular at sub-regions of the legs, were associated with increased CAC score independently in females only.
Since several epidemiological studies demonstrated coexistence, but no independent association, of vascular calcification with reduced BMD, it has been proposed that these conditions represent two independent age-related processes [
32,
33]. Although they are pathogenically connected [
13,
34,
35], the detailed mechanism(s) for the relationship between vascular calcification and BMD are still unclear. Low BMD is associated with an increased risk of CVD [
6,
10,
36] and predicts cardiac events and increased mortality in CKD patients and the general population [
6‐
8]. Low BMD and vascular calcification are both common features of the uremic phenotype [
37]. Kim et al. [
18] found - in a statistical model stratified by gender - when adjusting for age and comorbid conditions, there is no significant association of BMD with CAC. We report that in females, whereas lower BMD, in particular sub-regions of legs, was associated with a higher CAC score independently, even after adjustment for age, diabetes and hsCRP. No such associations were observed in males. Our observation that sex should be taken into consideration when links between bone health and vascular calcification are assessed corresponds with other reports showing associations between lower BMD and presence of CAC in ESRD [
6,
9,
10].
It is not known which specific bone location is optimal when studying links between BMD and vascular calcification. It is not evident how one should interpret our observation that tBMD and in particular BMD of legs rather than BMD of other central locations was associated to CAC score. In non-renal patients, lower BMD of the spine, but not the hip [
14], was associated with aortic calcification independently. In contrast, Disthabanchong et al. [
7] found that in haemodialysis patients, CAC was negatively associated with BMD of hip but not with BMD of lumbar spine. Uyama et al. [
35] found an inverse correlation between carotid plaque score and tBMD, but no association with BMD of lumbar spine. Banks et al. [
34] found in women that reduced BMD of the proximal femur associated with aortic calcification. Kohno et al. [
38] reported in male HD patients association of more bone loss of the ultra-distal radius with higer mortality. Those inconsistent results may be related to differences in population demographics, methods and anatomical sites of measurement of vascular calcification. Nevertheless, in this study, when examining BMD by DXA of different skeletal sub-regions, the correlation between BMD and CAC was more significant in legs than the spine. Since DXA may be influenced by signals from a calcified aorta [
7], we presume that the value for spine BMD may be overestimated.
Our report on a significant inverse relationship between BMD and CAC in females only accords with previous studies [
39,
40]. Bakhireva et al. [
41] reported that higher BMD was associated with reduced CAC of all skeletal sites after adjustment for confounders in women using hormone therapy but not in males, nor in females not on HT. Kim et al. [
18] also reported that a significant relationship between BMD and CAC existed only in women. In accordance, Campos-Obando et al. [
19] found significant associations between BMD loss and follow-up CAC only in the subgroup of women with lower estradiol levels. Kiel et al. [
42] from the Framingham cohort reported a lack of association between BMD loss and aortic calcification in men. Jensky et al. [
43] found the association of BMD and CAC to be stronger in women without dyslipidemia in the multi-ethnic study of atherosclerosis cohort. The independent inverse association between BMD and CAC observed in females only suggests the link between arterial calcification and bone mineralization are mediated by sex hormones.
In nondialysis male CKD patients, the reduction in testosterone levels observed with progressive CKD was inversely associated with endothelial dysfunction and exacerbated the risk of future cardiac events [
44]. Testosterone concentrations inversely correlate with CVD related and all-caused mortality in CKD patients [
45]. Studies investigating possible links of testosterone with vascular calcification have been inconsistent. Whereas two studies show no relationship in males and females [
46,
47]; Phillips et al. [
48] found in women an inverse relationship between free testosterone and severity of coronary disease. Increasing evidences points towards a protective effect (low testosterone levels associated with high cardiovascular risk) in both females [
49‐
51] and males [
52‐
55]. For the first time, we report on a significant inverse relationship between total testosterone and CAC score among the men. Testosterone has positive effects on endothelium by directly stimulating endothelium-derived nitric oxide [
56] and stimulate endothelial progenitor cells, which play a key role in endothelial repair [
57]. Furthermore, while testosterone has anabolic effects, including promotion of muscle strength and muscle mass, bone density and maturation, women have much lower levels of testosterone than men. On the other hand, deficiency of estrogen, whose beneficial effects on the coronary arteries have been reported only in women [
58], has been proposed to be a common mediator in the emergence of CVD and bone loss in postmenopausal women [
59]. The relative contributions of estrogen and testosterone to skeletal homeostasis that may initiate bone loss are still uncertain [
60]. It is can be speculated that dysregulation of testosterone and testosterone deficiency may have accounted for the observed sex difference with inverse association of BMD with CAC only in women while in men – when testosterone was added into the model –
higher BMD associated with higher CAC. This intriguing observation seems to provide further support for sex differentiating links between hormonal status, BMD and vascular calcification.
This study should be interpreted with some limitations. First, no conclusions can be made regarding causality because of the observational design of the study. Second, due to the limited number of participants and the risk of type-2 statistical error, our findings should be interpreted with caution. Third, there are limitations of the methods applied: for measurement of BMD, DXA may not be an ideal method, since it cannot distinguish between bone mineral content and extra-osseous calcifications; and, use of CT for measurement of CAC could not distinguish medial from intimal calcification [
15]. Fourth, data on hormone replacement therapy, menopause and sex hormone levels in women were not available.