Bronchoalveolar and serological parameters reflecting the severity of sarcoidosis

Study population

A diagnosis of sarcoidosis was established in 74 patients with newly diagnosed pulmonary sarcoidosis in accordance with recently described criteria 11. None of the patients included in this study had previously been treated with steroids; in all patients, noncaseating granulomas were identified by transbronchial and/or endobronchial biopsy. BAL and histological confirmation were performed via the same bronchoscopic procedure at initial presentation. The time point of bronchoscopy was regarded as the time point of diagnosis. Microbiological analysis of BALF was negative for bacteria, mycobacteria and fungi in all patients.

The 74 sarcoid patients were allocated to three groups: 10 newly diagnosed sarcoid patients had classical Löfgren's syndrome (bihilar adenopathy, arthritic symptoms and erythema nodosum) without indication for systemic steroid therapy at the time of diagnosis or during the following 6 months (Löfgren's syndrome group); 51 patients showed no evidence of deterioration in lung function parameters at the time of diagnosis or during the following 6 months and no extrapulmonary manifestation requiring systemic steroid therapy (stable disease group); 13 patients showed clear evidence of a progressing disease (significant decline in lung function parameters) or an extrapulmonary manifestation requiring therapy at the time of diagnosis or within the following 6 months (progressing disease group). Only one of these 13 patients was treated for severe systemic disease with multiple extrapulmonary manifestations of sarcoidosis (skin, eye, liver and severe general symptoms). This patient had radiological type I sarcoidosis; histological evidence of pulmonary involvement was determined by biopsy of the bronchial mucosa. The other 12 patients were treated due to there being clear evidence of progressing pulmonary sarcoidosis. The definitions used for detection of a significant decline in lung function parameters were the same as those recently described by Hunninghake et al. 12. In brief, for total lung capacity (TLC) and diffusing capacity of the lung for carbon monoxide (D_L,CO), a 10% decline from baseline was regarded as significant. For vital capacity (VC) and forced expiratory volume in one second (FEV₁), a 15% decline from baseline was regarded as significant.

The control group consisted of 48 individuals who underwent bronchoscopy for diagnostic reasons and were retrospectively free of any infectious, inflammatory or malignant lung disease. Microbiological analysis of the BALF was negative for bacteria, mycobacteria and fungi. Transbronchial biopsy was not performed in the control population, because the chest radiograph disclosed no evidence of interstitial or other abnormalities. The control group was age-matched and had a similar ratio of smokers and nonsmokers as the sarcoidosis cohort. The BALF characteristics of the control population are summarised in table 1⇓. An increase in total cell count and alveolar macrophage number and a decrease in the percentage of lymphocytes in smokers compared to nonsmokers were observed. The percentage of neutrophils did not differ significantly, whereas the total number of neutrophils was higher in smokers (0.11±0.05×10⁴ versus 0.05±0.01×10⁴ cells·mL⁻¹), but this difference did not reach significance. These observations are in line with the results of a large multicentric study performed in healthy individuals 13.

Lung function and arterial oxygen tension measurement and chest radiography

FEV₁, VC, TLC and FEV₁/VC were measured using a body plethysmograph (Master Screen Body; Jaeger, Würzburg, Germany) and D_L,CO was determined by the single-breath method. Values are expressed as percentage of the predicted value. All pulmonary function tests were performed according to the recommendations of the European Respiratory Society 14. Arterial oxygen tension (P_a,O2) was measured at rest without supplementary oxygen.

Chest radiography was performed in posterior/anterior and lateral projection. Three different experienced readers classified the radiographs according to the radiographical types of sarcoidosis (0–IV).

Bronchoalveolar lavage and preparation of bronchoalveolar lavage fluid cells

Bronchoscopy and BAL were performed as previously described 1. In brief, 300 mL sterile saline (0.9% NaCl) was instilled into a lingula or middle-lobe segment in 25 mL aliquots. Each aliquot was immediately aspirated and the recovered aliquots were pooled. Differential cell counts were determined using cytospin preparations of ≥400 cells (Cytospin II; Shandon Instruments, Sewickley, PA, USA). In cytospin preparations with percentages of cell populations near the established threshold values, ≥800 cells were counted. For immunoperoxidase staining 15, cells were fixed on poly‐l‐lysine-coated slides (Bio-Rad, Munich, Germany) and developed with a peroxidase/antiperoxidase technique using monoclonal antibodies directed against CD4, CD8, IL-2R (Ortho Diagnostic Systems, Neckargemünd, Germany) and human leukocyte antigen DR (Becton Dickinson, Heidelberg, Germany). Informed consent was obtained from all participants in this study.

Establishing the threshold of bronchoalveolar lavage fluid parameters

The large cohort of 48 controls was used to establish the threshold for the BAL differential cell counts. Since the percentages of BAL cells follow a nonparametric distribution, the 95th percentile of the control population was chosen as the threshold for the percentages of BAL lymphocytes, neutrophils and eosinophils. The 95th percentile was 11.3% for lymphocytes, 2.5% for neutrophils, 1.0% for eosinophils and 3.3 for the BAL lymphocyte CD4/CD8 ratio. For practical reasons, values of >15% lymphocytes, >3.0% neutrophils, >1.0% eosinophils and a CD4/CD8 ratio of >3.5 were regarded as elevated. These established thresholds are in accordance with the results of a large multicentric study performed in healthy individuals 13.

Serological parameters

Serum ACE, neopterin and sIL-2R levels were determined using commercially available kits, as described previously 6. C‐reactive protein (CRP) concentration was measured by an immunological method using rabbit antihuman CRP (DAKO A/S, Glostrup, Denmark) and an ELAN analyser (Eppendorf, Hamburg, Germany). The normal range was 0–0.50 mg·dL⁻¹. All normal ranges were used according to the recommendations of the manufacturers of the tests.

Statistical analysis

Data are expressed as mean±sem. Comparisons were performed using the Mann-Whitney U‐test. Differences between groups were evaluated with the Chi-squared test. Correlations between different parameters were determined using Spearman's rank correlation coefficient. A p‐value of <0.05 was regarded as significant.

Clinical characteristics of the study population

The clinical characteristics of the study population are summarised in table 2⇓. The mean age of the sarcoidosis group (n=74) and that of the controls (n=48) did not differ significantly. Among the sarcoid subgroups according to disease severity, patients with Löfgren's syndrome were slightly younger than those with stable disease (33.1±2.8 versus 38.7±1.6 yrs; p=ns) but significantly younger than those with progressive disease (33.1±2.8 versus 52.7±4.2 yrs; p<0.005). Patients with stable disease were also significantly younger than those with progressive disease (p<0.005).

The percentage of smokers was 23.1 in the control group and 25.4 in the sarcoidosis group. None of the sarcoid patients with progressive disease smoked.

The CRP level in the controls (0.48±0.11 mg·dL⁻¹) was within the normal range. The CRP level in the sarcoidosis group (1.43±0.30 mg·dL⁻¹) was significantly higher (p<0.01). This difference was due to a highly significant increase in CRP level in the Löfgren syndrome subgroup (6.0±1.3 mg·dL⁻¹; p<0.0001 versus controls and patients with stable disease (0.73±0.15 mg·dL⁻¹); p<0.001 versus patients with progressing disease (0.84±0.19 mg·dL⁻¹)). The CRP level in patients with stable or progressing disease did not differ significantly from that in controls. There was no correlation between CRP level and percentage of BALF neutrophils (ρ=0.26; p=ns).

The VC, TLC and D_L,CO of the sarcoidosis group were significantly lower than in the controls (p<0.05), but still within the normal range. The FEV₁/VC ratio did not differ between the sarcoidosis and control group. The lung function parameters of the Löfgren syndrome group did not differ from those of controls, whereas the VC and TLC of the patients with stable disease were significantly lower than in controls, but also still within the normal range. The VC and the D_L,CO of the sarcoid patients with progressing disease were significantly lower than in controls and sarcoid patients with Löfgren's syndrome or stable disease (table 2⇑). The FEV₁/VC ratio did not differ significantly between the sarcoidosis subgroups.

P_a,O2 did not differ significantly between the control and the entire sarcoidosis groups (n=74). The P_a,O2 of sarcoid patients with Löfgren's syndrome or stable disease was not significantly different from that in controls, whereas the P_a,O2 of sarcoid patients with progressive disease was significantly lower than in controls and sarcoid patients with Löfgren's syndrome or stable disease (table 2⇑).

Analysis of bronchoalveolar lavage fluid parameters

The percentage of BALF lymphocytes was significantly elevated in the sarcoidosis group compared to controls (15.9±1.4 versus 4.6±0.6%; p<0.0001). In all sarcoidosis subgroups, the percentage of BALF lymphocytes was significantly higher than in controls, whereas no significant differences were obtained between the sarcoid subgroups (fig. 1⇓). The CD4/CD8 ratio was significantly increased in the sarcoidosis group and in all sarcoidosis subgroups compared to controls. The highest CD4/CD8 ratio was observed in the Löfgren syndrome group (6.0±1.3) but this level was not significantly higher than that in patients with stable or progressing disease. The percentage of neutrophils was insignificantly higher in the sarcoidosis group than in controls (1.6±0.3 versus 0.8±0.1%). A highly significant increase in the percentage of BALF neutrophils was observed in sarcoid patients with progressing disease compared to controls (5.2±1.1 versus 0.8±0.1%; p=0.0005), as well as compared to patients with Löfgren's syndrome or stable disease (p<0.05 and p<0.0005, respectively). The percentage of BALF eosinophils was slightly elevated in the sarcoidosis group compared to controls (0.4±0.1 versus 0.1±0.1%; p<0.05). A highly significant increase in the percentage of BALF eosinophils was observed in sarcoid patients with progressing disease compared to controls (1.7±0.5 versus 0.1±0.1%; p<0.0001), as well as compared to patients with Löfgren's syndrome or stable disease (p<0.01 and p<0.0005, respectively).

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1.—

Percentages of a) lymphocytes, b) neutrophils and c) eosinophils, and d) CD4/CD8 ratio in bronchoalveolar lavage fluid (BALF) from controls (C), entire sarcoidosis cohort (S; n=74) and sarcoidosis subgroups (LS: Löfgren's syndrome; SD: stable disease; PD: progressing disease) according to disease severity. Vertical bars represent sem. *: p<0.05; ^#: p<0.005; ^¶: p<0.0005 versus control; ⁺: p<0.05; ^§: p<0.0005 versus progressing disease.

Similar results were obtained when analysing the absolute numbers of BALF cells (data and significance levels are given in table 2⇑). A highly significant positive correlation was observed between the percentage of BALF neutrophils and eosinophils (p<0.0001; ρ=0.54) and between the absolute number of both cell types (p<0.0001; ρ=0.55) in the sarcoidosis group (n=74). This positive correlation was even more pronounced as regards the subgroup of sarcoid patients with progressing disease (n=13) (percentage of neutrophils and eosinophils: p<0.005; ρ=0.93; absolute numbers of neutrophils and eosinophils: p<0.05; ρ=0.69).

Influence of smoking habits upon bronchoalveolar lavage fluid parameters in sarcoidosis

The total cell count was significantly lower in nonsmokers (n=59) than in smokers (n=15) (10.2±0.9×10⁴ versus 17.9±2.0×10⁴ cells·mL⁻¹; p<0.0005). The percentage of lymphocytes was significantly higher in nonsmokers than in smokers (17.9±2.0 versus 8.6±2.1%; p<0.005), whereas no differences were obtained comparing absolute numbers of lymphocytes (p=0.5). No significant differences between nonsmokers and smokers were obtained comparing CD4/CD8 ratio (p=0.9), neutrophil percentage (p=0.17) or absolute numbers of neutrophils (p=0.9). The percentage (0.55±0.16 versus 0.02±0.20; p<0.05) as well as the absolute number of eosinophils (0.065±0.021×10⁴ versus 0.002±0.002×10⁴ cells·mL⁻¹; p<0.05) was slightly elevated in nonsmokers compared to smokers.

Percentage of bronchoalveolar lavage fluid neutrophils and radiographical type of sarcoidosis

The relationship between percentage of BALF neutrophils, radiographical type of sarcoidosis and necessity for systemic steroid therapy is demonstrated in figure 2⇓. Only one of the 61 sarcoid patients without indication for therapy had an elevated percentage of BALF neutrophils (>3.0%). In contrast, nine of 13 patients with an indication for systemic steroid therapy had an elevated percentage of BALF neutrophils. An association between elevated percentages of neutrophils in BALF and necessity for systemic steroid therapy was observed in not only patients with advanced sarcoidosis (radiological types III and IV) but also sarcoid patients with earlier stages (radiological types I and II).

• Download figure
• Open in new tab
• Download powerpoint

Fig. 2.—

Relationship between radiographic type of sarcoidosis, percentage of bronchoalveolar lavage fluid (BALF) neutrophils and necessity for systemic steroid therapy (○: no therapy (n=61); •: therapy (n=13)). ═: upper limit of normal range.

Which bronchoalveolar lavage fluid parameters indicate a higher risk of necessity for steroid therapy?

Twenty-one sarcoid patients had an elevated percentage of BALF lymphocytes (>15%). Six of the 21 patients with BALF lymphocytosis and seven of 53 without BALF lymphocytosis needed corticosteroid treatment (p=ns). Sixteen patients showed an elevated CD4/CD8 ratio (>3.5). Three of the 16 patients with and 10 of 58 patients without an elevated CD4/CD8 ratio required treatment (p=ns). Ten patients showed an increased percentage of BALF neutrophils (>3.0%). Nine of the 10 patients with and four of 64 patients without an increased percentage of BALF neutrophils exhibited clear-cut indications for steroid treatment (p<0.0001) (fig. 2⇑). Nine patients had an increased percentage of BALF eosinophils (>1.0%). Six of the nine patients with and seven of 65 patients without an increased percentage of BALF eosinophils needed treatment with steroids (p<0.01).

Analysis of serological parameters

Mean levels of serum ACE, sIL-2R and neopterin were slightly elevated in the sarcoidosis group (fig. 3⇓). Serum ACE level was significantly lower in the Löfgren group, whereas there was no difference in serum ACE level between sarcoid patients with stable or progressing disease. The serum levels of sIL-2R and neopterin were significantly higher in sarcoid patients with progressive disease than in patients with stable disease or Löfgren's syndrome.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 3.—

Serum levels of the investigated serological markers of disease activity in the sarcoid subgroups. a) Serum angiotensin-converting enzyme (ACE), b) soluble interleukin‐2 receptor (sIL-2R) and c) neopterin (S: entire sarcoidosis cohort (n=74); LS: Löfgren's syndrome; SD: stable disease; PD: progressing disease). Vertical bars represent sem. ═: upper limit of normal range. *: p<0.05 versus stable disease and progressing disease; ^#: p<0.05 versus Löfgren's syndrome and stable disease.