Introduction
Rheumatoid arthritis (RA) is a chronic inflammatory musculoskeletal disease that affects ~0.8% of the adult population. RA also associates with an increased risk for cardiovascular disease (CVD) [
1], which is only partially explained by traditional CVD risk factors [
2]. The inflammatory processes of RA and CVD are remarkably similar, suggesting that RA itself may be an important risk factor for CVD [
3].
The leading cause of cardiac death in RA is myocardial infarction [
4]. A study in RA patients without overt coronary artery disease reported abnormalities in myocardial perfusion using contrast-enhanced magnetic resonance imaging (cMRI), and the degree of abnormality was related to the extent of RA disease-related inflammation [
5]. In another study, RA patients undergoing coronary angiography had greater myocardial ischaemia than healthy controls who were matched for classical CVD risk factors, but had similar levels of ischaemia to age-matched and sex-matched diabetic controls [
6]. Furthermore, myocardial ischaemia was evident despite the absence of obstructive coronary artery disease, suggesting a microvascular cause for the ischaemia [
6].
The current gold standard measure of microvascular coronary perfusion is coronary angiography; however, this procedure is invasive, carries considerable risk to the patient and cannot be repeated at regular intervals. Arterial tonometry using pulse wave analysis has recently gained interest in clinical research as it can non-invasively measure the central aortic pressure waveform and yield information on the augmentation index (AIx) (arterial stiffness), ejection duration (duration of ventricular contraction), pulse pressure (PP; pressure generated by the left ventricle during systole), mean blood pressure (MBP; product of cardiac output and systemic vascular resistance), tension time index (TTI; pressure load during systole), diastolic time index (DTI; pressure load during diastole) and subendocardial viability ratio (SEVR; a measure of coronary microvascular perfusion) [
7].
In particular, the SEVR reflects myocardial oxygen supply and demand, with low values representing a lesser degree of myocardial perfusion [
8]. The ratio of DTI versus TTI (that is, the integral of pressure and time during diastole and systole, respectively) has been shown to correlate well with the ratio of subepicardial to subendocardial blood flow, and therefore represents an index of subendocardial viability, defined as the SEVR (Buckberg index) [
9,
10]. The SEVR is an independent predictor of coronary flow reserve in patients with essential hypertension [
11], and is related to coronary artery calcification in patients with diabetes [
12]. In addition, low SEVR associates with severity of diabetes [
13], poor renal function [
14], low physical fitness [
15], and cigarette smoking [
16]. As such, the SEVR can be utilised as a surrogate measure of coronary microvascular perfusion in a number of different clinical populations.
To our knowledge only two studies have examined the SEVR in patients with RA [
17,
18]; one small pilot study revealed that the SEVR improved following 12 months of lipid-lowering treatment when compared with a group receiving only a placebo drug [
17], while in another study the SEVR was worse following 7 weeks of anti-inflammatory treatment in RA and ankylosing spondylitis patients [
18]. However, the small sample sizes of both studies, as well as the inclusion of different patient groups in the latter study, make these findings difficult to interpret.
The aims of the present study were: to examine associations between disease-related inflammation and classical CVD risk factors with SEVR in two separate cohorts of RA patients; and to prospectively assess the long-term effects of anti-inflammatory treatment on SEVR.
Results
General characteristics
The patient characteristics for both cohorts are presented in Table
1. The majority of patients were female and had low to moderate disease activity levels.
Table 1
Characteristics and pulse wave analysis for rheumatoid arthritis patients in both cross-sectional and longitudinal cohorts
Age (years) | 61 ± 12 | 59 ± 13 | 53 ± 13 |
Sex female | 176 (80) | 103 (81) | 21 (68) |
Disease-related characteristics | | | |
Disease duration (years) | 17 ± 12 | 10 ± 10 | 13 ± 13 |
Rheumatoid factor-positive (%) | 126 (79) | n/a | 23 (74) |
Erythrocyte sedimentation rate (mm/hour) | 12 (7 to 26) | 22 (12 to 38) (n = 112) | 10 (4 to 16) |
C-reactive protein (mg/l) | 3 (3 to 12) | 5 (3 to12) | 18 (9 to 33) |
DAS28 | 3.29 ± 1.26 | n/a | 4.32 ± 0.87 |
HAQ | 1.6 ± 0.9 | n/a | 2.19 ± 0.42 |
Classical CVD risk factors | | | |
Body mass index | 29 ± 6 | 33 ± 12 | 29 ± 6 |
Current smokers | 33 (15) | 40 (31) | 7 (23) |
Diabetes mellitus | 17 (8) | 10 (8) | 0 (0) |
Dyslipidaemia | 60 (27) | 30 (24) | 7 (23) |
SBP (mmHg) | 134 ± 18 | 134 ± 18 | 130 ± 14 |
DBP (mmHg) | 79 ± 11 | 79 ± 10 | 81 ± 11 |
Heart rate (beats/minute) | 74 ± 13 | 68 ± 11 | 73 ± 12 |
Total cholesterol (mmol/l) | 5.0 ± 1.0 | 5.2 ± 0.9 (n = 114) | 5.0 ± 0.9 |
HDL (mmol/l) | 1.5 ± 0.4 | 1.6 ± 0.7 (n = 102) | 1.5 ± 0.3 |
Triglycerides (mmol/l) | 1.3 ± 0.6 | 1.2 ± 0.4 (n = 95) | 1.5 ± 0.6 |
TC:HDL ratio | 3.5 ± 1.1 | 3.5 ± 0.8 (n = 102) | 3.5 ± 0.8 |
RA disease-specific medications | | | |
Methotrexate | 124 (65) | 76 (60) | 19 (61) |
Sulfasalazine | 44 (24) | 0 | 5 (16) |
Hydroxychloroquine | 50 (28) | 0 | 4 (13) |
Leflunomide | 15 (9) | 16 (13) | 0 (0) |
Prednisolone | 48 (26) | 85 (67) | 6 (19) |
NSAID | 34 (20) | 3 (2) | 6 (19) |
COX II inhibitors | 12 (7) | 0 (0) | 2 (7) |
Analgesic | 74 (40) | n/a | 8 (26) |
Folic acid | 118 (63) | 63 (50) | 16 (52) |
Anti-TNFα | 44 (20) | 51 (40) | -- |
CVD medications | | | |
Anti-hypertensive | 67 (36) | 68 (66) | 6 (19) |
Anti-hypercholesterolemics | 57 (31) | 23 (18) | 4 (13) |
Beta-blocker | 20 (11) | 28 (22) | 2 (7) |
Calcium channel-blocker | 24 (14) | 19 (15) | 0 (0) |
Pulse wave analysis | | | |
Ejection duration (m/second) | 312 ± 27 | 331 ± 26 | 320 ± 25 |
Pulse pressure (mmHg)b | 46 ± 13a | 54 ± 14 | - |
Mean pressure (mmHg) | 99 ± 12 | 97 ± 11 | 99 ± 10 |
Tension time index | 2,424 ± 402 | 2,485 ± 441 | 2,359 ± 368 |
Diastolic time index | 3,493 ± 462 | 3,443 ± 472 | 3,523 ± 651 |
SEVR (%) | 148 ± 27 | 142 ± 25 | 157 ± 33 |
Augmentation index (%) | 33 ± 9 | 34 ± 10 | 32 ± 9 |
Effects of medications on the subendocardial viability ratio
Univariate analysis of variance showed that the SEVR did not differ between patients receiving or not receiving steroid treatment in both the primary and validation cohorts. This was a similar finding for disease-modifying anti-rheumatic drug use, biologic agents, antihypertensives, anti-hypercholesterolemics, nonsteroidal anti-inflammatory drugs, and cyclooxygenase II inhibitors. However, the SEVR was higher in patients receiving β-blockers in the primary cohort only (167 ± 24 vs. 146 ± 27, P < 0.01).
Effects of CVD risk factors on the subendocardial viability ratio
Univariate analysis of variance was used to compare SEVR levels in patients with and without classical CVD risk factors. This analysis revealed that patients with diabetes had significantly lower SEVR than nondiabetic patients (127 ± 19 and 149 ± 26 respectively, P < 0.001). There was no difference in SEVR for any of the other CVD risk factors. Similar findings were also apparent in the validation cohort, except that the SEVR between diabetic and nondiabetic patients did not reach statistical significance (133 ± 31 and 142 ± 24 respectively, P = 0.28).
Univariate predictors of the subendocardial viability ratio
Linear and binary regression analysis was performed to determine univariate predictors (independent variable) of the SEVR (dependent variable) in patients with RA (see Table
2). This analysis revealed that gender was associated with the SEVR in the primary cohort, with females having lower SEVR than males (144 ± 25 and 162 ± 28 respectively,
P < 0.001). Similarly, gender was also associated with the SEVR in the validation cohort; with females having a lower SEVR than males (139 ± 25 and 151 ± 24 respectively,
P = 0.04). From the disease-related variables, log ESR and log CRP were inversely associated with the SEVR, and a positive association was found with log disease duration in patients in the primary cohort (Table
2). Only PP and heart rate were inversely associated with the SEVR from the classical CVD risk factors. However, there were trends for an inverse association between body mass index, total cholesterol and SEVR. In the validation cohort, log CRP (but not disease duration and ESR) was inversely associated with the SEVR (Table
2). As with the primary cohort, PP (marginally MBP) and heart rate were the CVD risk factors associated with the SEVR.
Table 2
Regression analysis between general characteristics, disease-related characteristics, classical cardiovascular disease risk factors and the SEVR
General characteristics | | |
Age | β = 0.02, P = 0.79 | β = 0.03, P = 0.73 |
Gender |
0.97 (0.96 to 0.99)*
|
0.98 (0.96 to 0.99)*
|
Disease-related characteristics | | |
Log disease duration |
β =
0.21,
p
= 0.01
| β = 0.12, P = 0.21 |
RF positivity | 0.90 (0.99 to 1.02) | n/a |
Log ESR |
β = -
0.20,
P
= 0.01
| β= -0.144, P = 0.131 |
Log CRP |
β = -
0.23,
P
= 0.003
|
β = -
0.28,
P
= 0.002
|
DAS28 | β = -0.12, P = 0.09 | n/a |
HAQ | β = -0.11, P = 0.16 | n/a |
Classical CVD risk factors | | |
Body mass index | β = - 0.13, P = 0.05 | β = - 0.19, P = 0.18 |
Pulse pressure |
β = -
0.23,
P
= 0.004
|
β = -
0.21,
P
= 0.017
|
Mean blood pressure | β = -0.10, P = 0.15 | β = -0.17, P = 0.05 |
Heart rate |
β =
-0.64,
P
< 0.001
|
β = -
0.76
P
< 0.001
|
Total cholesterol | β = -0.12, P = 0.09 | β = -0.14, P = 0.14 |
TC:HDL ratio | β = -0.02, P = 0.76 | β = -0.09, P = 0.35 |
Triglycerides | β = -0.01, P = 0.90 | β = 0.01, P = 0.94 |
Multivariate predictors of the subendocardial viability ratio in the primary cohort
Stepwise multivariate regression was performed to examine the relationship between significant univariate predictors presented in the analysis above (independent variables) and the SEVR (dependent variables). The individual components that were entered into the model were gender, log disease duration, log ESR, log CRP, PP and heart rate. The entry probability was 0.05 and none of the variables were forced back into the model. From this analysis a significant model emerged (adjusted R2 = 0.631, F4, 76 = 35.3, P < 0.001). Significant variables within the model included heart rate (β = -0.75, P < 0.001), PP (β = -0.39, P < 0.001), log ESR (β = -0.29, p = 0.001) and log CRP (β = 0.18, P = 0.03).
Multivariate predictors of the subendocardial viability ratio in the validation cohort
Similar multivariate regression as above was performed in the validation cohort. The individual components that were entered into the model as independent variables were gender, log CRP, PP and heart rate, with the SEVR entered as the dependent variable. From this analysis a significant model was apparent (adjusted R2 = 0.69, F = 72.1, P < 0.001). Significant variables within the model included heart rate (β = -0.783, P < 0.001), PP (β = -0.258, P < 0.001), and gender (β = -0.249, P < 0.01). In an alternative model without heart rate, log CRP was, independently of gender and PP, associated with the SEVR (β = -0.238, P < 0.05).
Inflammation and components of the subendocardial viability ratio
To examine the effects of inflammation on the components used to calculate the SEVR, further linear regression analysis was performed with DTI, TTI and heart rate entered separately as dependent variables, and log ESR, log CRP as well as DAS28 entered separately as independent variables. This analysis showed that DTI was inversely associated with all parameters of disease activity, but no such associations were apparent for TTI (see Table
3). Heart rate was inversely associated with log ESR and log CRP only. In the validation cohort, TTI was positively associated with log CRP (
β = 0.28,
P = 0.002) while heart rate was inversely associated with log CRP (
β = -0.27,
P = 0.01) (Table
3).
Table 3
Regression analysis between individual components of the SEVR and inflammation in the primary cohort
Primary cohort | | | |
DTI |
β = -
0.26,
P
= 0.001
|
β = -
0.17,
P
= 0.03
|
β = -
0.20,
P
= 0.004
|
TTI | β = 0.02, P = 0.85 | β = 0.13, P = 0.08 | β = -0.006, P = 0.38 |
HR |
β =
0.18,
P
= 0.02
|
β =
0.32,
P
< 0.001
| β = 0.13, P = 0.006 |
Validation cohort | | |
DTI | β = -0.02, P = 0.81 | β = -0.053, P = 0.56 | n/a |
TTI | β = 0.16, P = 0.10 |
β =
0.28,
P
= 0.002
| n/a |
HR | β = 0.85, P = 0.37 |
β = -
0.27,
P
= 0.01
| n/a |
Longitudinal study
The effect of anti-inflammatory treatment on a range of outcomes was considered using generalised estimating equations (Table
4). Each outcome was considered separately, with the time that measurements were taken included as a categorical factor. This analysis gave an overall significance for the change over time, which tested the null hypothesis that the outcome considered remained constant for the year after the commencement of treatment. There was significant evidence against this hypothesis for CRP (
P < 0.001), ESR (
P = 0.004), DAS28 (
P < 0.001), MBP (
P = 0.002) and AIx (
P < 0.001), with the only nonsignificant outcome being the SEVR (
P = 0.30). Hence, for those outcomes that were significant, it can be concluded that the average measurements changed over time.
Table 4
Generalised estimating equations testing the effect of time on various measurements.
Significance of change over time | | | | | |
P value |
< 0.001
|
0.004
|
< 0.001
| 0.30 |
0.002
|
< 0.001
|
Baseline | | | | | | |
Meanb | 8.7 (5.7 to 13.2) | 16.8 (11.3 to 25.0) | 4.3 (0.17) | 153.3 (142.1 to 165.5) | 98.9 (95.2 to 102.8) | 31.9 (1.56) |
2 weeks | | | | | | |
Meanb | 4.2 (2.8 to 6.4) | 10.8 (7.4 to 15.9) | 2.8 (0.26) | 154.8 (144.9 to 165.3) | 94.4 (90.2 to 98.8) | 30.2 (1.74) |
P valuec |
< 0.001
|
< 0.001
|
< 0.001
| 0.69 |
0.010
| 0.11 |
3 months | | | | | | |
Meanb | 5.5 (3.7 to 8.3) | 11.4 (6.9 to 18.9) | 2.8 (0.27) | 160.4 (149.6 to 172.0) | 92.9 (88.0 to 98.1) | 32.3 (1.98) |
P valuec |
< 0.001
| 0.05 |
< 0.001
| 0.14 |
0.003
| 0.75 |
1 year | | | | | | |
Meanb | 2.8 (1.6 to 5.1) | 11.9 (7.9 to 17.7) | 2.6 (0.29) | 154.1 (140.5 to 169.1) | 92.7 (87.3 to 98.5) | 29.6 (2.15) |
P valuec |
< 0.001
| 0.33 |
< 0.001
| 0.85 |
0.002
| 0.13 |
To detect where these changes occurred, pairwise comparisons were made between the baseline and all of the subsequent measurement times. Where this was significant, it implied that the outcome considered changed significantly after the treatment began. As can be seen in Table
4, in each case that a pairwise comparison was significant, the observed mean was smaller than that at baseline; hence, the treatment brought about a significant reduction in these outcomes.
A secondary analysis considered the effect of CRP and ESR on the other factors considered above (Table
5). Generalised estimating equations were again used to account for the potential correlation between repeated measurements made on the same patient. In each model, either the CRP or ESR was entered as a continuous predictor, with the SEVR, MBP or AIx as the dependent variable. The resulting
P value then represented the strength of the relationship between the two variables in the model. The coefficient demonstrated the increase in the dependent variable that would be expected for each increase in the predictor variable. Owing to the necessity of log transformations, this relationship was not necessarily linear.
Table 5
Generalised estimating equations testing effect of CRP and ESR on SEVR, MBP and augmentation index
SEVRa | -0.031 (-0.059 to -0.004) |
0.02
| -0.028 (-0.079 to 0.023) | 0.28 |
MBPa | 0.009 (-0.009 to 0.026)b | 0.34b | -0.009 (-0.033 to 0.015)b | 0.48b |
AIx | 5.434 (1.769 to 7.299) |
0.001
| -1.887 (-4.877 to 1.104) | 0.22 |
The ESR was not found to be a significant predictor of any of these outcomes, whilst CRP was found to have significant effects on both the AIx (P < 0.001) and the SEVR (P = 0.02). For the former, the resulting coefficient implied that a 10-fold increase in CRP increases the AIx by 5.4 (95% confidence interval = 1.8 to 7.3). Because both of these variables are log10 transformed, the relationship between CRP and the SEVR is more complex. The model showed that a 10-fold increase in CRP reduces the log10 of the SEVR by 0.03 (95% confidence interval = 0.00 to 0.06). Applying this to a real-world example, an increase of CRP from 1 to 10 would be expected to reduce the SEVR from 174 to 162. A 10-fold increase in CRP hence reduces the SEVR by approximately 12.
Discussion
The present findings from two separate cohorts of RA patients revealed that SEVR, a non-invasive measure of subendocardial perfusion, is associated with disease-related inflammation along with classical CVD risk factors such as the heart rate, PP and diabetes. In particular, these data generate the hypothesis that inflammation impairs myocardial perfusion, as assessed by the SEVR, via the stimulation of the autonomic nervous system; that is, increased heart rate and especially a decrease in DTI. Alternatively, as suggested by the validation cohort data, the SEVR may also be reduced due to increased TTI in the presence of higher inflammation.
Coronary artery disease is typically silent in RA, with a greater frequency of unrecognised myocardial infarction and sudden cardiac death [
22]. This highlights the importance of identifying myocardial perfusion defects as early as possible. Assessment of the SEVR is non-invasive, simple to perform, carries no risk to the participant and can be repeated at regular intervals. The SEVR primarily reflects diastolic dysfunction and plays an important role in the development of CVD [
23], and associates with invasive measures of coronary microvascular function such as coronary flow reserve [
11]. In addition, the SEVR is related to a number of clinical conditions including diabetes [
13], impaired renal function [
14], low physical fitness [
15], and cigarette smoking [
16]. Assessment of the SEVR thus appears to be a valid surrogate measure of coronary microvascular perfusion, particularly in a research setting with healthy volunteers and in patients without overt CVD. In a 2-year prospective study conducted by Protogerou and colleagues in frail older participants exhibiting the blood pressure J-curve phenomenon (that is, presenting higher mortality in the presence of low diastolic blood pressure), the SEVR was significantly impaired in the higher mortality group - providing further evidence that an impaired SEVR could have an impact on CVD, independently from other classical markers of cardiovascular health (such as intima-media thickness, pulse wave velocity, left ventricular mass - all of which were similar between the groups) [
24].
The inflammatory nature of RA and CVD is strikingly similar [
3], and on this basis it has been hypothesised that RA disease-related inflammation contributes to the excess CVD risk present in RA [
25]. The present study examined associations between disease-related inflammation and the SEVR in a large cohort of patients and demonstrated that the SEVR was associated with all markers of disease activity and inflammation (DAS28, ESR and CRP). Furthermore, although there was no evidence that SEVR changed significantly in response to anti-inflammatory treatment in the longitudinal study, the latter analysis found a significant negative relationship between CRP and SEVR (
P = 0.02). The results of the model showed that a 10-fold increase in CRP is associated in a reduction of 0.031 in the log
10 SEVR. To our knowledge only one other study, with a small sample size of RA patients (
n = 17), has assessed the effects of inflammation on the SEVR in RA, and revealed that the SEVR was worse following 7 weeks of treatment with anti-TNFα despite a reduction in disease activity and inflammation [
18]. However, the findings of that study need to be interpreted with caution as the treatment group also consisted of 13 ankylosing spondylitis patients, and analysis was performed by categorising the RA patients and ankylosing spondylitis patients into one group. In addition, the reduction in SEVR following treatment (ΔSEVR 7.4%) was smaller than the nonsignificant difference in SEVR between patients and healthy controls at baseline (ΔSEVR 10.1%), thus limiting the clinical relevance of this finding [
18].
Studies assessing coronary microvascular function consistently demonstrate inflammation to be an important contributor to myocardial ischaemia. For example, Kobayashi and colleagues demonstrated myocardial perfusion defects in RA patients using cMRI [
5]. Furthermore, they reported that abnormal cMRI was associated with higher DAS28, and patients with impaired cMRI had significantly higher levels of ESR and CRP than patients with normal cMRI [
5]. Another study in RA revealed that myocardial perfusion defects were as a result of abnormalities in the coronary microvasculature and that this was associated with high disease activity [
6]. These cross-sectional findings suggest that inflammation might more readily affect microvascular function, rather than macrovascular function, but further prospective studies specifically examining this hypothesis are warranted.
In the present work, inflammation was inversely associated with DTI and positively associated with heart rate. These findings suggest that inflammation may lower the time for diastolic filling of the heart while simultaneously increasing cardiac workload due to an elevated heart rate. Both of these actions would have a negative impact on cardiac perfusion and contribute to myocardial ischaemia, especially as the heart rate was inversely associated with the SEVR in multivariate analysis. Inflammation therefore appears to have a detrimental association with myocardial ischaemia, possibly due to negative actions on cardiac perfusion and workload. Alternatively, as shown in the validation cohort, higher CRP levels may be associated with lower SEVR due to increased TTI (that is, afterload (PP)), presumably induced by the described effect of inflammation and heart rate acceleration on aortic stiffness.
Another important finding in the current study was that the SEVR was positively associated with disease duration. Patients with greater disease duration therefore had better myocardial perfusion. This finding appears to contradict the general hypothesis that longer disease duration is associated with greater CVD risk [
26]. However, a number of studies have revealed an increased risk for myocardial infarction within 1 year of RA diagnosis [
22,
27], and increased risk of hospitalisation from CVD occurs within 7 years of RA diagnosis [
28]. Furthermore, studies utilising other surrogate measures of coronary endothelial function have revealed that changes in flow-mediated dilatation appear to be already evident within 1 year of RA diagnosis [
29], but do not appear to be further influenced by disease duration [
30,
31]. Similarly, carotid artery atherosclerosis is apparent even in patients with a recent diagnosis of RA [
32,
33] - and while some studies have found an association between carotid artery atherosclerosis and longer disease duration [
34,
35], other studies have not [
36,
37]. Collectively, these studies suggest that increased CVD risk is evident early in the disease course, with reduced risk with longer disease duration. One possible explanation for these findings could be that optimal treatment strategies that effectively control RA symptoms as well as CVD risk are more likely to be achieved with longer disease duration, and as a result the patient will have more stable disease, better myocardial perfusion and lower CVD risk. Further prospective studies that assess the SEVR in patients newly diagnosed with RA and who are followed over the course of their disease are warranted.
The SEVR was found to inversely associate with PP in the present cohort, but not with MBP. This finding supports the results of a meta-analysis which revealed that PP but not MBP was an independent predictor of cardiovascular complications and all-cause mortality in older hypertensive patients [
38]. PP is generated by the left ventricle during systole and is dampened by the compliance of the aorta. Loss of aortic compliance with age or CVD will lead to greater PPs, and there is evidence that arterial stiffness is increased in RA [
39]. In addition, conditions such as hypertension can increase afterload (the pressure the left ventricle has to overcome to eject blood into the systemic circulation), which results in increased left ventricular workload and consequently greater myocardial oxygen demand, increasing the susceptibility for myocardial ischaemia [
40]. The prevalence of hypertension in RA is high and the condition is often suboptimally treated [
41]. In the present cohort, 44% of patients were hypertensive but the SEVR did not differ between hypertensive and nonhypertensive patients. This lack of difference is possibly because the majority of hypertensive patients were on angiotensin-converting enzyme or angiotensin II subtype-1 receptor inhibitors as well as β-blockers. Such treatment increases myocardial perfusion and decreases myocardial workload [
42], hence making a difference in the SEVR between hypertensive and nonhypertensive patients unlikely. This is supported by our finding that the SEVR was better in patients receiving β-blockers (compared with those who were not).
RA patients with diabetes had lower SEVR than nondiabetic patients, in line with findings from another study in type 1 diabetics [
13]. A number of factors, including increased glucose levels, can perpetuate damage to the vasculature in diabetic patients [
43], but there is growing evidence that autonomic dysfunction can adversely alter heart rate and vascular tone, thereby contributing to myocardial ischaemia in diabetes [
16,
44,
45]. Importantly, there is also evidence for autonomic dysfunction in RA [
46], with inflammation being a potential mediating factor [
47]. Given that RA and diabetes have a similar CVD risk burden [
48] and vascular profile [
49], further research examining the role of cardiac autonomic neuropathy on multiple cardiovascular parameters (including the SEVR) is required.
The strength of the present study is the inclusion of two separate cohorts of well-characterised RA patients along with the assessment of a novel and non-invasive measure of myocardial ischaemia. In addition, the 1-year prospective study allowed observation of the effect of anti-inflammatory treatment on the SEVR. Importantly, the findings were replicated in both cohorts, demonstrating the strength of the findings. The limitations of the study include the prospective assessment of the SEVR following administration of three different types of anti-inflammatory treatment (anti-TNFα, intravenous corticosteroids and rituximab) whose mode of action could differentially affect the vasculature. However, there was no difference in parameters of pulse wave analysis between treatment types at any time point (data not shown). Another limitation in the prospective arm of the study was that it was not possible to determine whether parameters of pulse wave analysis were already impaired at baseline due to an absence of a healthy control group. Nevertheless, the average AIx relative to the age of the prospective cohort would be considered normal, and the AIx did improve with treatment at 1 year - which tends to suggest that irreversible vascular alterations were not evident in this cohort. Finally, the prospective arm of the study was possibly underpowered to detect a change in SEVR following treatment; further prospective studies with a large sample size as well as including a more thorough examination of the factors that affect the ventricular-vascular coupling are therefore warranted.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
AS and ADP participated in the design of the study, recruited patients, performed assessments of pulse wave analysis, conducted data analysis and drafted the manuscript. JH performed statistical analysis of longitudinal data. JPS conducted laboratory analysis. EZ, PPS and GK participated in the design of the study and helped with writing the manuscript. All authors read and approved the final manuscript.