Introduction
Systemic sclerosis (SSc) is a severe connective tissue disease characterized by vascular, immune, and fibrotic changes in the skin and some internal organs
Thus, we hypothesized that microvascular abnormalities with disturbed capillary architecture objectified on NVC could be related to an impairment of selective factors reflecting disturbances of angiogenesis, endothelium damage, and vasculogenesis. To test this hypothesis, we assessed whether NVC changes were associated with peripheral blood or serum levels of endothelial factors in SSc.
Materials and methods
Patient sets
Two different cohorts were used in this study. All patients gave informed consent for all procedures, which were carried out with local ethics committee approval (Comité de Consultation pour la Protection des Personnes se prêtant à la Recherche Biomédicale (CCPPRB) Paris-Cochin).
Discovery cohort
The first patient set consisted on consecutive patients with SSc referred to the Rheumatology A Department over a 6-month period for systematic follow-up. Eligible patients were those who had been on a stable treatment regimen for at least 3 months, including vasodilators (calcium channel blockers, angiotensin-converting enzyme inhibitors, endothelin-receptor antagonists, PDE5 inhibitors) and immunosuppressive drugs (methotrexate, azathioprine, and prednisone dosage ≤ 10 mg/day). No patient was treated with cyclophosphamide or prostacyclins at the time of this study.
Clinical assessments
We systematically collected the following data: age, disease duration (date of the first non-Raynaud symptom), duration of Raynaud phenomenon, cutaneous subset according to the criteria reported by LeRoy
Routine laboratory assessments
Routine laboratory studies obtained on the morning of hospital admission included complete blood cell count, Westergren erythrocyte sedimentation rate (ESR), C-reactive protein (CRP) level, serum creatinine concentration, levels of proteinuria and von Willebrand factor antigen (ELISA, VIDAS von Willebrand; BioMérieux, Marcy l'Etoile, France), and tests for anticentromere (immunofluorescence on Hep2 cells) and antitopoisomerase-I antibodies (counter immunoelectrophoresis).
Pulmonary and cardiac assessments
Echocardiography was performed by a senior cardiologist according to the American Society of Echocardiography recommendations. In particular, left ventricular ejection fraction (LVEF) was determined by using the Simpson method, and systolic PAP (sPAP) was based on the tricuspid and/or pulmonary regurgitation, adding 10 mm Hg for auricular pressure. Pulmonary hypertension was suspected at baseline or during follow-up based on (a) an estimated echocardiographic systolic pulmonary arterial pressure (sPAP) > 40 mm Hg, Or (b) a DLCO < 50% predicted in absence of pulmonary fibrosis; or (c) unexplained dyspnea, as previously published
Pulmonary involvement was assessed with chest radiograph, computed tomography, and measurement of forced vital capacity (FVC) and the diffusing capacity for carbon monoxide/alveolar volume (DLCO/AV) ratio.
Replication cohort
This second patient set consisted on patients with SSc recruited during a patient meeting (business meeting of the Association des Sclérodermiques de France, Strasbourg, 27 April, 2012). Age, disease duration, and cutaneous subset according to the criteria reported by LeRoy
Nailfold videocapillaroscopy
NVC was performed for all patients of the two cohorts. Patients were asked not to smoke and take caffeinated drinks for at least 4 hours before NVC, and to remain at least 15 minutes at 22°C to 23°C before NVC.
Collection and blinding of the NVC images
The nailfolds of the second, third, fourth, and fifth fingers were examined bilaterally in each patient by two independent investigators blinded for the serum status of SSc patients (discovery cohort: JA, replication cohort: JA and PS), by using an optical probe videocapillaroscope equipped with a ×200 magnification contact lens and connected to image-analysis software (Videocaps, DS MediGroup, Milan, Italy). Four consecutive fields extending over 1 mm, in the middle of the nailfold, were studied per finger
Qualitative assessment of NVC images
The following NVC definitions were used for the qualitative assessment of the NVC patterns.
The early NVC scleroderma pattern: the combination of few enlarged/giant capillaries, few capillary microhemorrhages, a relatively well-preserved capillary distribution, and no evident loss of capillaries.
The active NVC scleroderma pattern: frequent giant capillaries, frequent capillary microhemorrhages, moderate loss of capillaries, mild disorganization of the capillary architecture, and absent or mild ramified capillaries.
The late-NVC scleroderma pattern: irregular enlargement of the capillaries, few or absent giant capillaries and microhemorrhages, severe loss of capillaries with large avascular areas, disorganization of the normal capillary array, and ramified/bushy capillaries (7). The Additional File
EPC and CEC cell sorting and flow-cytometry quantification
EPC and CEC quantification were performed only in the discovery cohort. Quantification of EPCs and CECs was precluded in the replication cohort because this procedure required fresh blood samples, and the patient meeting was organized in another city than the one where our laboratory is located. As used in previous reports, 20-ml samples of heparinized venous blood were taken at rest from the forearm, in the morning, at the same time as samples collected from hospitalized patients for routine analysis
Serum levels of endothelial markers
Serum was isolated from the peripheral blood of all patients included in the discovery and replication cohorts. In the replication cohort, sera was also taken at rest from the forearm, in the morning, and stored locally before shipment to our laboratory, in the days after the patient meeting. Serum levels of eight endothelial factors that have been shown to be implicated in SSc (VEGF, placenta growth factor (PlGF), sVCAM, angiopoietin-2, endoglin, endostatin, endothelin-1 and Tie-2) were measured by using the quantitative sandwich enzyme-linked immunosorbent assay (ELISA) technique (Quantikine kits; R&D systems)
Table S1. Analytic range, and intraassay and interassay coefficients of variation of the quantitative sandwich enzyme-linked immunosorbent assay for each endothelial marker.
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Statistical analysis
All data are presented as median (range) for continuous variables and numbers and percentages for categoric variables, unless stated otherwise. The χ2 test was used to compare categoric variables. In that case, patients with early and active NVC patterns were merged and further compared with patients with the late-NVC pattern. Comparisons between the three NVC patterns were by a nonparametric Kruskal-Wallis test. A multiple linear regression analysis was also performed for all variables identified with
Results
Study population
The discovery cohort consisted of 60 consecutive SSc patients (46 women, 77%), with a median (range) age of 53.5 years (28 to 81 years) and median (range) disease duration of 9 years (1 to 50 years). Thirty-six (60%) patients had the diffuse cutaneous subset, and 24, the limited. Their baseline characteristics are shown in Table
Characteristics of the 60 patients with systemic sclerosis included in the discovery cohort
Age (years), median (range)
53.5 (28-81)
Disease duration (years), median (range)
9 (1-50)
Limited/Diffuse cutaneous subset,
36 (60)/24 (40)
Modified Rodnan skin score > 14,
19 (32)
History of digital ulcers,
29 (47)
Pulmonary fibrosis on CT scan,
28 (47)
Pulmonary arterial hypertension on RHC,
4 (7)
Positive antinuclear antibodies (> 1/160),
53 (88)
Positive antitopoisomerase-1 antibodies,
28 (47)
Positive anticentromere antibodies,
12 (20)
FVC < 75% predicted,
13 (22)
DLCO/AV < 75% predicted,
23 (38)
Treatment with calcium channel blockers,
60 (100)
Treatment with angiotensin-converting enzyme inhibitors,
19 (32)
Treatment with endothelin-receptor antagonists and/or PDE5 inhibitors,
12 (20)
DLCO/AV, diffusing capacity for carbon monoxide/alveolar volume; FVC, forced vital capacity; PDE5, phosphodiesterase type 5; RHC, right heart catheterization.
The replication cohort consisted on 43 patients with SSc (33 women, 77%), with a median (range) age of 57 years (34 to 80 years) and median (range) disease duration of 7 years (1 to 29 years). Fifteen (35%) patients had the diffuse cutaneous subset, and 28, the limited.
Qualitative capillaroscopic assessment
Fourteen (23%) patients had an early-, 22 (37%), an active-, and 24 (40%), a late-NVC SSc pattern in the discovery cohort. In the replication cohort, eight (19%) patients had an early-, 20 (46%) an active-, and 15 (35%) a late-NVC pattern.
Levels of endothelial factors
To assess the validity of flow cytometry and ELISA measurements, we compared the levels of endothelial markers observed in SSc patients with the values obtained in a population of 20 healthy age- and sex-matched controls
Table S2. Levels of the different endothelial markers in patients with systemic sclerosis in the discovery cohort: comparison with a population of 20 healthy controls issued from previous publications.
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Figure S1. Representative pictures of the three nailfold videocapillaroscopy (NVC) patterns, as compared with a normal examination.
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Levels of endothelial factors and NVC patterns
In univariate analysis focused on vascular factors, patients from the discovery cohort and with the late-NVC pattern exhibited significantly lower EPC levels than did patients with early and active patterns (median EPC levels, 31/106 Lin-mononuclear cells in the late-NVC pattern versus 61 and 82/106 Lin-mononuclear cells in the early- and active-NVC patterns, respectively;
Nailfold videocapillaroscopy patterns and endothelial marker levels in peripheral blood or serum of patients with systemic sclerosis included in the discovery cohort
Capillaroscopy pattern
Early
Median (range)
Active
Median (range)
Late
Median (range)
EPCs (106 Lin-mononuclear cells)
61 (29-573)
82 (21-300)
31 (5-300)
< 0.0001
CECs (106 Lin-mononuclear cells)
81 (10-342)
36 (5-155)
77 (6-472)
0.4
VEGF (pg/ml)
518 (161-1,028)
493 (156-1,146)
814 (189-1,564)
0.01
PlGF (pg/ml)
9.6 (4.6-24.2)
9.9 (0.7-19.6)
10.5 (2.3-26.5)
0.8
sVCAM-1 (ng/ml)
766 (482-1,828)
694 (354-1,405)
767 (459-1,314)
0.4
Tie-2 (ng/ml)
24.4 (12.9-29.4)
21.1 (14.1-27.1)
22.2 (16-39.6)
0.3
Endostatin (ng/ml)
185 (88-477)
139 (54-178)
150 (22-662)
0.3
Endoglin (CD105) (ng/ml)
3.7 (1.9-5.0)
3.9 (2.8-5.6)
3.5 (2.6-5.1)
0.5
Endothelin-1 (pg/ml)
1.5 (1.0-3.6)
2.5 (0.9-7.2)
1.7 (0.4-3.1)
0.02
Angiopoietin-2 (pg/ml)
2,166 (1241-3,312)
2,016 (1,249-4,027)
2202 (1,512-5,148)
0.5
von Willebrand factor antigen (%)
180 (95-266)
169 (69-304)
170 (83-302)
0.9
Levels of circulating endothelial progenitor cells (Lin-7AAD-CD133+CD34+VEGFR2+ cells) (A, B) and VEGF serum levels (C, D) in the discovery cohort according to the nailfold videocapillaroscopy pattern
Levels of circulating endothelial progenitor cells (Lin-7AAD-CD133+CD34+VEGFR2+ cells) (A, B) and VEGF serum levels (C, D) in the discovery cohort according to the nailfold videocapillaroscopy pattern.
In the discovery cohort, higher VEGF serum levels were observed in the late-NVC pattern (median VEGF serum levels, 814 pg/ml), as compared with the early- (518 pg/ml) and active- (493 pg/ml) NVC patterns (
Serum VEGF levels in the replication cohort (A), and combined cohort (B), according to the nailfold videocapillaroscopy pattern
Serum VEGF levels in the replication cohort (A), and combined cohort (B), according to the nailfold videocapillaroscopy pattern.
Endothelin-1 serum levels were significantly higher in the active pattern (2.5 pg/ml) compared with the early and late patterns (1.5 and 1.7 pg/ml;
No association was observed between the levels of other serum markers and NVC patterns in the discovery cohort (Table
In multivariable analysis performed with multiple linear regression, including EPC counts, VEGF serum levels, and endothelin serum levels, only EPC counts (
SSc disease characteristics and NVC patterns in the discovery cohort
The χ2 analysis performed revealed several associations between the late-NVC pattern and SSc-related disease characteristics (Table
Association between nailfold videocapillaroscopy patterns and disease characteristics of patients with systemic sclerosis included in the discovery cohort
NVC pattern
Multiple linear regression
(
Early/active
(
Late
(
Age, median (range)
58
53
0.2
Females,
27 (75)
19
0.9
Disease duration, median (range)
9.91
7.20
0.2
Diffuse cutaneous subset,
13 (36)
11 (46)
0.9
Modified Rodnan skin score > 14,
6 (17)
13 (54)
0.005*
0.42
0.0008
History of digital ulcers,
13 (36)
16 (67)
0.03*
0.25
0.03
Pulmonary fibrosis,
15 (42)
13 (54)
0.5
Pulmonary arterial hypertension on RHC,
2 (6)
2 (8)
0.9
Positive antitopoisomerase antibodies,
12 (33)
16 (67)
0.02*
Positive anticentromere antibodies,
9 (25)
3 (13)
0.4
FVC < 75,
5 (14)
8 (33)
0.1*
0.29
0.01
DLCO/VA < 75%,
9 (25)
14 (58)
0.02*
Treatment with angiotensin-converting enzyme inhibitors,
8 (22)
11 (46)
0.09*
Treatment with endothelin-receptor antagonists and/or PDE5 inhibitors,
4 (11)
8 (33)
0.08*
DLCO/AV, diffusing capacity for carbon monoxide/alveolar volume; FVC, forced vital capacity; NVC, nailfold videocapillaroscopy; PDE5, phosphodiesterase type 5; RHC, right heart catheterization.
* Variables included in multiple regression analysis
In multiple linear regression analysis performed for all variables identified with
Angiogenic factors, SSc disease characteristics, and NVC patterns
We next tested an alternate multiple linear regression model including both angiogenic markers independently associated with the late-NVC pattern (circulating EPCs and VEGF serum levels) and SSc-related disease characteristics associated univariately with
In this model, lower EPC counts (
Alternate multiple linear regression model performed in the discovery cohort and including both angiogenic factors independently associated with the late-NVC pattern and SSc-related disease characteristics associated univariately with
NVC pattern
Multiple
linear
regression
(
Early/Active
(
Late
(
Modified Rodnan skin score > 14,
6 (17)
13 (54)
0.005*
0.50
< 0.0001
History of digital ulcers,
13 (36)
16 (67)
0.03*
0.25
0.04
Positive antitopoisomerase antibodies,
12 (33)
16 (67)
0.02*
FVC < 75,
5 (14)
8 (33)
0.1*
DLCO/VA < 75%,
9 (25)
14 (58)
0.02*
Treatment with angiotensin-converting enzyme inhibitors,
8 (22)
11 (46)
0.09*
Treatment with endothelin-receptor antagonists and/or PDE5 inhibitors,
4 (11)
8 (33)
0.08*
EPCs (106 Lin-mononuclear cells), median (range)
64 (21-573)
31 (5-300)
< 0.0001*
-0.45
0.005
VEGF (pg/ml), median (range)
470 (156-1,146)
814 (189-1,564)
0.01*
0.37
0.01
DLCO/AV, diffusing capacity for carbon monoxide/alveolar volume; FVC, forced vital capacity; NVC, nailfold videocapillaroscopy. * Variables included in multiple regression analysis
Discussion
This is the first study to show decreased EPC counts and increased VEGF serum levels in patients with the late-NVC pattern.
Reduced EPC numbers in the late-NVC pattern suggest that deficient vasculogenesis may contribute to the severe loss of capillaries observed in this pattern. Indeed, decreased EPC numbers can lead to insufficient endothelial repair and depressed new blood vessels formation that could be related to the extensive areas of desertification. Decreased EPC levels in this stage may be consistent with decreased mobilization from the bone marrow, as suggested in a previous study
The severe capillary loss observed in the late-NVC pattern might also be related to decreased angiogenesis. This insufficient angiogenesis might be related to decreased levels of proangiogenic factors. However, we detected in two independent and homogeneous cohorts increased VEGF serum levels in SSc patients with the late-NVC pattern, compared with patients with the early- or active-NVC pattern. Thus, VEGF upregulation may appear as an insufficient compensatory mechanism to stimulate angiogenesis. In addition, the observation of lower EPC counts in the late-NVC pattern also supports that vasculogenesis is not sufficiently compensated by VEGF upregulation. This result is in accordance with those of other research groups that found significantly higher VEGF levels in the late stages of the disease, as compared with the levels in patients with recent onset
We did not find any differential concentration of other proangiogenic markers (PlGF, angiopoietin-2, and Tie-2) between the different NVC patterns. One recent previous study identified a trend for higher angiopoietin-2 levels in patients with the late-NVC pattern with respect to those with an early/active pattern
We also determined whether SSc-disease characteristics might be associated with NVC patterns. No association was noted between the late-NVC pattern and disease duration, which supports that patients with early disease may experience severe vascular loss not sufficiently compensated by new-vessel formation. We found that the late-NVC pattern was associated in univariate analysis with more-severe vascular manifestations (history of digital ulcers) or with the presence of markers of a more-diffuse SSc subset (mRSS > 14 and antitopoisomerase-I antibodies). Multivariate analysis confirmed the independent association between the late-NVC pattern and the following characteristics: history of digital ulcers, mRSS > 14, and an FVC < 75% of predicted; which support a more-severe and fibrotic propensity of the late-NVC pattern. These results are consistent with previously published data, which showed that patients with the late-NVC pattern have an increased risk to experience digital ulcers, more-severe skin thickening, and decreased FVC and DLCO, compared with patients with early and active patterns
Our study has several limitations that deserve consideration. Our study is limited by its observational design, and any pathogenic link emerging from this type of study should be taken very cautiously. Our sample size was too limited to assess adequately disease phenotype associations in specific subsets of patients, especially those with confirmed pulmonary arterial hypertension, or those with active digital ulcers. In addition, our NVC assessment was only qualitative, based on pattern recognition. Next to associations between endothelial factors and qualitative NVC assessment, efforts should be further made to find associations with quantitative assessment, based on counting of hallmark parameters of the SSc pattern. Now quantitative assessment has to find a definite place in research settings and also in daily practice. Thus, further evaluation of endothelial markers with some recently proposed quantitative index/scores might be performed to confirm our findings obtained with pattern recognition
Conclusions
Our data revealed decreased EPC counts and VEGF upregulation in patients with the late-NVC pattern. Further studies are now needed to determine the respective role of EPCs and VEGF in endothelial injury and endothelial repair in SSc.
Abbreviations
CEC: circulating endothelial cell; CRP: C-reactive protein; DLCO/AV: diffusing capacity for carbon monoxide/alveolar volume; EPC: endothelial progenitor cell; ESR: erythrocyte sedimentation rate; mRSS: modified Rodnan skin score; NVC: nailfold videocapillaroscopy; PlGF: placenta growth factor; sPAP: systolic pulmonary artery pressure; SSc: systemic sclerosis; sVCAM: soluble vascular cell adhesion molecule; VEGF: vascular endothelial growth factor.
Competing interests
Prof. Allanore and Dr. Avouac have received research grants and honoraria from Actelion and Pfizer (less than $10,000 USD each). The remaining authors have no competing interest.
Authors' contributions
JA participated in the design of the study, performed nailfold videocapillaroscopy, participated to the analysis and interpretation of the data, performed the statistical analysis, and wrote the manuscript. MV performed the EPC/CEC quantification by flow cytometry and ELISA measurement, and collected the clinical data. VS participated in the analysis and interpretation of the data. PS performed nailfold videocapillaroscopy. BR performed the EPC/CEC quantification with flow cytometry and ELISA measurement. AS, CP, CF, GC, and MC participated in the analysis and interpretation of the data. YA conceived the study, participated in its design, participated in the analysis and interpretation of the data, and performed the statistical analysis. All authors drafted, read, and approved the final manuscript.