Ian R. Doyle

Lung hyperpermeability and asthma prevalence in schoolchildren: Unexpected associations with the attendance at indoor chlorinated swimming pools

Aims: To study whether exposure to nitrogen trichloride in indoor chlorinated pools may affect the respiratory epithelium of children and increase the risk of some lung diseases such as asthma. Methods: In 226 healthy children, serum surfactant associated proteins A and B (SP-A and SP-B), 16 kDa Clara cell protein (CC16), and IgE were measured. Lung specific proteins were measured in the serum of 16 children and 13 adults before and after exposure to NCl3 in an indoor chlorinated pool. Relations between pool attendance and asthma prevalence were studied in 1881 children. Asthma was screened with the exercise induced bronchoconstriction test (EIB). Results: Pool attendance was the most consistent predictor of lung epithelium permeability. A positive dose-effect relation was found with cumulated pool attendance and serum SP-A and SP-B. Serum IgE was unrelated to pool attendance, but correlated positively with lung hyperpermeability as assessed by serum SP-B. Changes in serum levels of lung proteins were reproduced in children and adults attending an indoor pool. Serum SP-A and SP-B were already significantly increased after one hour on the pool side without swimming. Positive EIB and total asthma prevalence were significantly correlated with cumulated pool attendance indices. Conclusions: Regular attendance at chlorinated pools by young children is associated with an exposure dependent increase in lung epithelium permeability and increase in the risk of developing asthma, especially in association with other risk factors. We therefore postulate that the increasing exposure of children to chlorination products in indoor pools might be an important cause of the rising incidence of childhood asthma and allergic diseases in industrialised countries. Further epidemiological studies should be undertaken to test this hypothesis.

Changes in serum pneumoproteins caused by short-term exposures to nitrogen trichloride in indoor chlorinated swimming pools.

Nitrogen trichloride (NCl3) is an irritant gas released in the air of indoor pools sanitized with chlorine-based disinfectants. In the present study we investigated the effects of NCl 3 on the pulmonary epithelium of pool attendees by measuring the leakage into serum of three lung-specific proteins (pneumoproteins): the alveolar surfactant-associated proteins A and B (SP-A and SP-B) and the bronchiolar 16 kDa Clara cell protein (CC16). These pneumoproteins were measured in the serum of 29 recreational swimmers (16 children and 13 adults) before and after attending a chlorinated pool with a mean NCl3 concentration of 490 μg m-3. Pneumoprotein changes in serum were also studied in 14 trained swimmers performing an intensive 45 min standardized swimming session in a chlorinated pool (mean NCl3 concentration of 355 μg m-3) and for the purposes of comparison in a non-chlorinated pool sanitized by the copper/silver method. Serum CC16 was not increased in recreational swimmers, but in trained swimmers serum levels of this protein peaked immediately after strenuous exercise, both in the copper/silver pool and in the chlorinated pool. This acute increase in airway permeability is probably the consequence of the mechanical stress on the epithelial barrier caused by overinflation and/or hyperventilation during intense exercise. Serum levels of SP-A and SP-B were unaffected by strenuous exercise in the copper/silver pool. The two proteins were, however, significantly increased in a time-dependent manner in recreational and trained swimmers attending the chlorinated pool. The intravascular leakage of SP-A and SP-B was already statistically significant after only 1 h of exposure to pool air without exercising and remained elevated for 12 h after. These changes were not associated with decrements in lung function. The ability of NCl3 to acutely disrupt the lung epithelium barrier was confirmed in mice using serum CC16 and plasma proteins in bronchoalveolar lavage fluid as permeability markers. The significance of these permeability changes induced by NCl3 in the deep lung is presently unknown. In view of the increasing and widespread human exposure to this gas not only in indoor pools but also in a variety of other situations, these findings warrant further study.

Serum levels of CC16, SP-A and SP-B reflect tobacco-smoke exposure in asymptomatic subjects.

Since the 16-kDa bronchiolar Clara cell protein (CC16) and the alveolar surfactant-associated proteins (SP)-A and -B leak into the circulation when parenchymal health is disturbed, the aim of this study was to determine whether their serum levels could serve as early peripheral markers of tobacco smoke-induced epithelial injury. Sixty-nine (51 yrs (32–54) median (25–75th percentile)) nonsmokers and 54 (42 yrs (31–53)) asymptomatic smokers were enrolled in the study. Serum levels of SP-A did not differ between subjects (270 (208–389) versus 259 (168–392) µg·L−1), however, CC16 levels decreased (10.6 (8.7–14.6) versus 7.6 (6.0–11.2) µg·L−1) and SP-B levels increased (2,529 (2,091–2,943) versus 3,053 (2,613–4,188) µg·L−1) in the smokers. When tobacco smoke exposure, serum creatinine (renal index), age and sex were used as independent variables, CC16 was negatively influenced by cumulative smoking and positively influenced by age. SP-A and -B were negatively influenced by creatinine and positively influenced by cumulative smoking. Serum SP-B was inversely correlated with forced expiratory volume in one second/vital capacity, suggesting an association between obstructive disease and parenchymal lung health. The authors suggest that serum surfactant-associated proteins-A and -B reflect increased alveolocapillary leakage whereas Clara cell secretory protein 16 reflects tobacco smoke-induced Clara cell toxicity. Their evaluation may allow the effects of tobacco smoke on different levels of the respiratory tract, cellular toxicity and epithelial leakage to be distinguished.

Relationship of anti-GM-CSF antibody concentration, surfactant protein A and B levels, and serum LDH to pulmonary parameters and response to GM-CSF therapy in patients with idiopathic alveolar proteinosis

Background: Conventional measures of the severity of alveolar proteinosis (AP) include alveolar-arterial oxygen gradient ([A – a]Do2), vital capacity (VC), and carbon monoxide transfer factor (Tlco), but alternative serological measures have been sought. Granulocyte-macrophage colony stimulating factor (GM-CSF) neutralising autoantibody is found in patients with idiopathic acquired AP. We have investigated the interrelationships between the levels of this antibody and those of surfactant protein (SP)-A and -B, lactate dehydrogenase (LDH), and conventional measures of disease severity, and the capacity of these parameters to predict the response to rhGM-CSF treatment. Methods: Blood levels of anti-GM-CSF antibodies, SP-A, SP-B, LDH, and [A – a]do2, VC, and Tlco were measured before rhGM-CSF treatment and every 2 weeks thereafter in 14 patients with AP. Results: At baseline, high levels of anti-GM-CSF antibodies and increased SP-A and SP-B levels were seen in all patients, and LDH was raised in 83%. SP-A was highly correlated with [A – a]do2, VC, and Tlco (p≤0.02), but other markers were not. Only a normal LDH level was predictive of a response to rhGM-CSF treatment (p=0.03). During treatment a correlation between conventional and serological variables within patients was seen only between SP-A and [A – a]do2 (p=0.054), LDH levels and [A – a]do2 (p=0.010), and LDH levels and VC (p=0.019). Conclusions: Of the serological parameters studied, only SP-A and LDH levels were correlated with conventional measures of disease severity, with LDH most accurately reflecting [A – a]Do2 and vital capacity. Only a normal LDH level predicted a higher likelihood of response to treatment with GM-CSF.

Prolonged alveolocapillary barrier damage after acute cardiogenic pulmonary edema

ObjectivesTo determine whether acute cardiogenic pulmonary edema is associated with damage to the alveolocapillary barrier, as evidenced by increased leakage of surfactant specific proteins into the circulation, to document the duration of alveolocapillary barrier damage in this setting, and to explore the role of pulmonary parenchymal inflammation by determining if circulating tumor necrosis factor-&agr; is increased after acute cardiogenic pulmonary edema. DesignProspective, observational study. SettingCritical care, cardiac intensive care, and cardiology wards of a tertiary-care university teaching hospital. PatientsA total of 28 patients presenting with acute cardiogenic pulmonary edema and 13 age-matched normal volunteers. InterventionsCirculating surfactant protein-A and -B and tumor necrosis factor-&agr; were measured on days 0 (presentation), 1, 3, 7, and 14. Clinical markers of pulmonary edema were documented at the same times. Measurements and Main ResultsSurfactant protein-A and -B were elevated on day 0 compared with controls (367 ± 17 ng/mL vs. 303 ± 17 and 3821 ± 266 ng/mL vs. 2747 ± 157 [mean ± sem], p < .05), and although clinical, hemodynamic and radiographic variables improved rapidly (p < .001), surfactant protein-A and -B rose further until day 3 (437 ± 22, p < .001, 4642 ± 353, p < .01). Tumor necrosis factor-&agr; was elevated at presentation (p < .05), doubled by day 1 (6.98 ± 1.36 pg/mL, p < .05), remained elevated on day 3 (5.72 ± 0.96 pg/mL, p < .05), and peak levels were related to chest radiograph extravascular lung water score (rp = 0.64, p = .003). ConclusionsAlthough the initial increase in plasma surfactant protein-A and -B may represent hydrostatic stress failure of the alveolocapillary barrier, the prolonged elevation, when hemodynamic abnormalities have resolved, and the delayed elevation of tumor necrosis factor-&agr; are consistent with pulmonary parenchymal inflammation, which may further damage the alveolocapillary barrier. This prolonged physiologic defect at the alveolocapillary barrier after acute cardiogenic pulmonary edema may partly account for the vulnerability of these patients to recurrent pulmonary fluid accumulation.

Partitioning lung and plasma proteins: circulating surfactant proteins as biomarkers of alveolocapillary permeability.

1. The alveolocapillary membrane faces an extraordinary task in partitioning the plasma and lung hypophase proteins, with a surface area approximately 50‐fold that of the body and only 0.1–0.2 μm thick.

Plasma Surfactant Protein-B A Novel Biomarker in Chronic Heart Failure

Background—In chronic heart failure (CHF), elevated pulmonary microvascular pressure (Pmv) results in pulmonary edema. Because elevated Pmv may alter the integrity of the alveolocapillary barrier, allowing leakage of surfactant protein-B (SP-B) from the alveoli into the circulation, we aimed to determine plasma levels of SP-B in CHF and their relation to clinical status. Methods and Results—Fifty-three outpatients with CHF had plasma SP-B and N-terminal proBNP (NT-proBNP) assayed, in addition to a formalized clinical assessment at each clinic review over a period of 18 months. The control group comprised 19 normal volunteers. Plasma SP-B was elevated in CHF (P<0.001), and levels increased with New York Heart Association classification (P<0.001). SP-B correlated with objective clinical status parameters and NT-proBNP. During follow-up, major cardiovascular events occurred in patients with higher plasma SP-B (P<0.01) and NT-proBNP (P<0.05). Furthermore, on conditional logistic regression analysis, only SP-B was independently associated with CHF hospitalization (P=0.005). The 53 patients underwent a total of 210 outpatient visits. When the diuretic dosage was increased on clinical grounds, SP-B had increased 39% (P<0.001) and NT-proBNP had increased 32% (P<0.001). Conversely, at the next visit, SP-B fell 12% (P<0.001), whereas NT-proBNP fell 39% (P<0.001). Conclusions—Plasma SP-B is increased in CHF, and levels are related to clinical severity. Furthermore, within individual patients, SP-B levels vary with dynamic clinical status and NT-proBNP levels. Because plasma SP-B is independently associated with CHF hospitalization, it may, by virtue of its differing release mechanism to NT-proBNP, be a clinically useful biomarker of the pulmonary consequences of raised Pmv.

Determinants of serum levels of surfactant proteins A and B and Clara cell protein CC16.

Increased leakage of surfactant proteins A and B (SP-A and SP-B) and Clara cell secretory protein (CC16) from the air spaces into the circulation occurs in a range of respiratory conditions. However, circulating levels depend not only on the rate of entry into the circulation, but also on the rate of clearance. In order to clarify the role of the kidney in the clearance of these proteins, serum levels were related to markers of glomerular filtration in 54 non-smoking patients with varying degrees of renal dysfunction, none of whom had respiratory disease or were receiving dialysis at the time of sampling. Serum SP-A was related to SP-B (r=0.53, p<0.001) and to CC16 (r=0.33, p<0.02). Similarly, SP-B was related to CC16 (r=0.39, p<0.004). Stepwise multiple linear regression analysis suggested that serum SP-A and SP-B are influenced by age (∼20 and ∼25% of variance, respectively), whereas CC16 is determined by renal function and, to a lesser extent, by body weight (∼63% of variance in total). We conclude that CC16 is cleared from blood by the renal route, whereas SP-A and SP-B are not. Serum SP-A and SP-B are influenced by age, which we speculate reflects increased damage to the alveolocapillary barrier.

Plasma surfactant protein-B: a novel biomarker in chronic heart failure

Background—In chronic heart failure (CHF), elevated pulmonary microvascular pressure (Pmv) results in pulmonary edema. Because elevated Pmv may alter the integrity of the alveolocapillary barrier, allowing leakage of surfactant protein-B (SP-B) from the alveoli into the circulation, we aimed to determine plasma levels of SP-B in CHF and their relation to clinical status. Methods and Results—Fifty-three outpatients with CHF had plasma SP-B and N-terminal proBNP (NT-proBNP) assayed, in addition to a formalized clinical assessment at each clinic review over a period of 18 months. The control group comprised 19 normal volunteers. Plasma SP-B was elevated in CHF (P<0.001), and levels increased with New York Heart Association classification (P<0.001). SP-B correlated with objective clinical status parameters and NT-proBNP. During follow-up, major cardiovascular events occurred in patients with higher plasma SP-B (P<0.01) and NT-proBNP (P<0.05). Furthermore, on conditional logistic regression analysis, only SP-B was independently associated with CHF hospitalization (P=0.005). The 53 patients underwent a total of 210 outpatient visits. When the diuretic dosage was increased on clinical grounds, SP-B had increased 39% (P<0.001) and NT-proBNP had increased 32% (P<0.001). Conversely, at the next visit, SP-B fell 12% (P<0.001), whereas NT-proBNP fell 39% (P<0.001). Conclusions—Plasma SP-B is increased in CHF, and levels are related to clinical severity. Furthermore, within individual patients, SP-B levels vary with dynamic clinical status and NT-proBNP levels. Because plasma SP-B is independently associated with CHF hospitalization, it may, by virtue of its differing release mechanism to NT-proBNP, be a clinically useful biomarker of the pulmonary consequences of raised Pmv.

Fractional exhaled NO and serum pneumoproteins after swimming in a chlorinated pool.

PURPOSE The purpose of this study was to examine whether a swimming session performed in a pool sanitized with chlorine-based agents induces lung inflammation, modifies lung epithelium permeability, and alters lung function. METHODS Eleven volunteers performed two standardized swimming sessions: one in a nonchlorinated indoor swimming pool and the other one in a chlorinated indoor pool. Lung inflammation was assessed by fractional exhaled nitric oxide (FE(NO)). Changes in lung epithelium permeability were estimated by measuring the surfactant-associated proteins Type A and Type B (SP-A and SP-B), the Clara cell protein (CC16), and the Krebs von den Lungen-6 protein (KL-6). Lung function tests were also performed. All measurements were carried out in basal conditions, after training completion and 3 h postexercise. Nitrogen trichloride (NCl3), the most concentrated gas derived from pool water chlorination, was measured in each pool during the swimming sessions. RESULTS NCl3 ranged from 160 to 280 microg x m(-3) in the air of the chlorinated pool and was undetectable in the nonchlorinated one. Lung function was affected neither by the exercise session nor by the type of sanitation. Serum pneumoproteins were unchanged excepted SP-A which decreased by 8% after exercise in the chlorinated pool (P < 0.05). FE(NO) increased by 34% (P < 0.05) after exercise in the nonchlorinated pool, whereas it was unaffected in the chlorinated one. CONCLUSIONS At concentrations lower than 300 microg x m(-3), NCl3 in an indoor chlorinated pool, does not produce short-term changes in lung function or in epithelial permeability. The unchanged FE(NO) found in the chlorinated pool after exercise suggests that chlorination might inhibit NO-induced vasodilation observed during exercise.