Abstract
Airway neuropeptides, in particular calcitonin gene-related peptide (CGRP), are likely to be important in the pathogenesis of chronic cough. The present authors evaluated the following: 1) the relationship between cough sensitivity and bronchoalveolar lavage (BAL) neuropeptides; and 2) the effect of reflux oesophagitis (RO) on cough, cough sensitivity and BAL neuropeptides in children not selected for cough. It was hypothesised that CGRP would be increased in children with chronic cough and would relate to cough sensitivity.
Capsaicin cough sensitivity was performed in children undergoing gastro-duodenal endoscopy. CGRP, substance P and neurokinin A were measured in BAL obtained nonbronchoscopically. Children were defined as “coughers” if chronic cough was present.
Coughers (n = 21) had significantly reduced cough sensitivity but were just as likely as noncoughers (n = 19) to have RO. The median CGRP was significantly higher in coughers with oesophagitis than in noncoughers with oesophagitis. CGRP significantly negatively correlated to cough sensitivity in coughers but not in noncoughers.
Elevated calcitonin gene-related peptide, but not substance P or neurokinin A, is only associated with chronic cough in children when oesophagitis coexists. Calcitonin gene-related peptide in bronchoalveolar lavage relates to cough sensitivity and is likely to be important in the pathophysiology of chronic cough.
Chronic cough is a commonly encountered symptom and can result from a wide variety of pulmonary and nonpulmonary conditions. Irrespective of its aetiology, chronic cough causes significant morbidity 1, 2 and is associated with enhanced cough sensitivity in children 3, 4 and adults 5–7. Cough sensitivity is commonly measured using capsaicin cough challenge 7, 8.
Understanding the mechanisms of disease processes is an important step in the advance of medicine. In the area of cough, the majority of such data have been obtained from animal studies whereby significant interspecies differences exist 9. The mechanisms associated with chronic cough in humans include neurogenic inflammation through the sensory pathway 10–12 and vanilloid receptor (VR) activation 13. VRs (such as transient receptor potential vanilloid-1 (TRPV-1) receptors) have been found to be likely contributors to an enhanced cough response in chronic persistent cough 13, 14. In 29 adults with chronic persistent cough from diverse causes, Groneberg et al. 13 described a significant correlation between capsaicin tussive response and the number of TRPV-1-positive nerves of airway mucosal biopsy specimens. In animals, the cellular distribution of TRPV-1 neurons is such that they occur in sensory neurons 15. Sensory nerve stimulation primarily involves neurogenic inflammation whereby neuropeptides, such as calcitonin gene-related peptide (CGRP) and substance P (SP), play a key role 9, 12.
In the airways, neuropeptides thought to be particularly important include SP, neurokinin (NK)A and CGRP 9, 16. SP, NKA and CGRP are pro-inflammatory sensory neuropeptides 9, although the pulmonary effects of CGRP are also anti-inflammatory 16. In particular, CGRP has been shown to be important in the mechanism of chronic cough 16, 17. In human studies, increased CGRP but not SP immunoreactive nerves were found in biopsies of adults with chronic cough 18. These adults also had significantly increased cough sensitivity to capsaicin (i.e. a reduced threshold to elicit a cough response) 18. In animal models, gastro-oesophageal reflux (GOR) is associated with sensory nerve stimulation 19.
Whether data in airway mucosal biopsies can be related to bronchoalveolar lavage (BAL) in the pathophysiology of chronic cough is unknown. To date, no studies that have related cough sensitivity to these key neuropeptides (CGRP, SP, NKA) in BAL. Indeed, there is currently no data on BAL quantification of these neuropeptides in children either with or without chronic cough. BAL provides different and complementary information to mucosal biopsy, with the advantage that a broader range of airways are sampled, both in terms of the numbers and size of the airways sampled.
There are several unique and important features of the population used in the present study. Prior studies have used selected populations of adults presenting with cough 13, 18, and this may select individuals with an abnormal airway response. In order to avoid this potential bias in the present study, children have been studied presenting for upper gastro-intestinal endoscopy where there was no selection bias for coughing 20, 21. In addition, the present authors have evaluated neuropeptides in children where data are scant. Gastro-oesophageal reflux disease (GORD; symptoms or complications of GOR 22) is associated with chronic cough but the mechanism and “cause and effect” remains controversial in humans 23. The present authors conducted a study to evaluate the following: 1) the relationship between cough sensitivity and BAL neuropeptides; and 2) the effect of reflux oesophagitis on cough, capsaicin cough sensitivity and BAL neuropeptides in children unselected for the presence of chronic cough. It was hypothesised that CGRP would be increased in children with chronic cough and would relate to capsaicin cough sensitivity.
METHODS
Children <14 yrs of age undergoing elective flexible upper gastro-intestinal endoscopy were invited to participate in the study, as previously described 20, 21. Briefly, children were enrolled for the study on the morning of their procedure (flexible upper endoscopy performed under general anaesthesia including endotracheal intubation). Medical history was obtained from a parent on a standardised proforma for all children. Parent(s) also scored their child's cough on a validated cough visual analogue scale of 1 (no cough) to 10 (most severe cough) 24. Exclusion criteria of children were as follows. 1) Neuro-developmental abnormalities; 2) known underlying cardiorespiratory disease other than asthma; and 3) a clinical history of primary aspiration (coughs and chokes with feeds at least twice a week). Children were defined as “coughers” (C+) if the parents or consultant (gastroenterologist or respiratory paediatrician) had elicited a history of cough in association with GORD 20. Reflux oesophagitis (RO) was considered present if histology of an oesophageal biopsy showed RO, as determined by pathologists blinded to the child's respiratory history. Written consent was obtained and the study approved by the human ethics committee of the Royal Children’s Hospital (Brisbane, Queensland, Australia).
Capsaicin cough sensitivity test and spirometry were performed on children aged ≥6 yrs prior to endoscopy. The cough sensitivity test described specifically for children was performed using a single inhalation dosimeter technique 8. Outcomes of cough sensitivity test were defined as the concentration of capsaicin that stimulated ≥2 coughs (C2) and defined that which stimulated ≥5 coughs (C5). Increased cough sensitivity is represented by a lower C2 and/or lower C5 values, i.e. a lower concentration of capsaicin required to elicit coughs. Spirometry was performed using a turbine spirometer (Kit; Cosmed, Rome, Italy) and Australian values were used for predictive values 25.
BAL and BAL examination
BAL was obtained using a standardised and repeatable 26 nonbronchoscopic technique. Briefly, with the child's head turned to the left, a catheter was passed as far as possible through the endotracheal tube, ensuring that it went beyond the estimated carina site. Two aliquots of sterile normal saline (1 mL·kg−1 to a maximum of 20 mL) were instilled and suctioned into separate mucus traps. The second aliquot was used for BAL cellularity and neuropeptide analysis. The first aliquot was used for microbiology, the results of which have been previously described 20. A cell count was performed (by blinded cytologists) on the cell suspension, cytocentrifuge slides were prepared and stained (modified Wright's stain, Diff Quik; Lab Aids, Narrabeen, NSW, Australia) for cell differential profile. Protease inhibitor (see Appendix) was added to the BAL supernatant, and the mixture was immediately frozen and kept at -80°C until it needed to be thawed for analysis.
Analysis of CGRP, NKA and SP
The BAL specimens were prepared for assay of neuropeptides using an established technique using Sep-Paks® (C18 Sep-Pak; Waters, Milford, MA, USA). Specimens were applied to a C18 Sep-Pak, washed and eluted with an acetonitrile–trifluoroacetic acid 1% solution (60:40 volume/volume). The eluate was dried using a rotary evaporator and the residue reconstituted in buffer prior to assay. The specimen was reconstituted to concentrate the sample by two-fold. The recovery of peptides via this extraction procedure is >90%.
NKA was measured using an in-house (The Queen's University of Belfast, Belfast, UK) radioimmunoassay. The antibody was raised in guinea pig to synthetic human NKA (Bachem, St Helens, UK). The antibody was directed to the amino terminal; it cross-reacted fully with NKB and neuropeptide K, and cross-reaction with SP was <0.1%. Radiolabelled NKA was purchased from GE Healthcare (St Giles, UK). The limit of the assay was 2 ng·L−1. There was no external quality control system available for NKA; however, three internal controls were added to each assay batch. The coefficient of inter- and intra-assay variation was 9.8 and 6.2%, respectively. CGRP was measured by radioimmunoassay using a commercial antiserum to human CGRP (antibody code RAS-6012N; Peninsula Laboratories, San Carlos, CA, USA). The antibody cross-reacted with human CGRP-I and -II. Radiolabel was purchased from GE Healthcare. Three internal quality control specimens were included in each assay batch. The limit of detection was 2 ng·L−1 and inter- and intra-assay variation was 11.5 and 7.5%, respectively. SP was measured by ELISA using a commercial kit (catalogue number DE1400; R&D Systems, Minneapolis, MN, USA). The assay did not cross-react with NKA, NKB or neuropeptide K. The limit of detection of the assay was 8 ng·L−1.
Statistical analysis
Children were categorised into coughers (C+) and noncoughers (C-) with RO (RO+) and without RO (RO-). The Chi-squared test was used to compare categorical variables between groups, with a continuity correction used when the table cell was <5. Data were not normally distributed and, thus, nonparametric analyses were used: the Mann–Whitney U-test for comparisons between two groups and the Kruskal–Wallis test when >2 groups were compared. Medians and interquartile ranges (IQRs) were used for all descriptive data. Kendall's tau-b was used to examine correlation among variables as the sample size was small. A two-tailed p-value <0.05 was considered significant.
RESULTS
The median age of the 40 children (26 males) recruited was 9.6 yrs (IQR 6.4; IQRs are given throughout as the 75th quartile minus the 25th quartile). Most (n = 36, 90%) children were clinically suspected of having GORD, and oesophagitis was present in 23 (57.5%) children. Coughers (n = 21) were just as likely as noncoughers (n = 19) to have GORD (p = 0.538). Spirometry was normal in all children who could perform spirometry (n = 27), with a median forced expiratory volume in one second of 99.8% predicted, and a forced vital capacity of 100.3% pred. In the C+ group, cough was present for a median (IQR) time of 160 (186) weeks. The median cough score was significantly higher in the C+ group (5 (3.5)) than in C- (median score of 1, i.e. no cough; p<0.0001). No difference was observed in the cough score or length of cough between RO+ and RO- groups (p = 0.57 and 0.96, respectively).
There was no significant difference in BAL cellular profile (percentages of neutrophils, macrophages, lymphocytes, eosinophils or total cell count) between the C+ and C- groups (table 1⇓). However, the RO- group had a significant but small increase in BAL neutrophil percentage when compared with the RO+ group (p = 0.01). No difference was observed in BAL percentages of macrophages, lymphocytes and eosinophils in children with and without RO. There was no difference in CGRP, SP or NKA levels between either the C+ and C- groups or the RO+ and RO- groups. Coughers had a lower C2 but not C5. Capsaicin cough sensitivity was similar between RO+ and RO- groups (table 1⇓).
When grouped by the presence of cough and RO, C2 was significantly different among the groups (p = 0.013), but there was no significant difference in BAL cellularity, SP or NKA (table 2⇓). C2 was lowest in the C+ RO+ group and highest in the C- RO- group. C5 and CGRP values were just outside the significant value (p = 0.06 and 0.07, respectively). In two group comparisons, CGRP was significantly different between C+ RO+ and C- RO+ groups (p = 0.02; fig. 1⇓), but not between the other groups (p-values of 0.07–0.74). Similarly, C5 was significantly lower in C+ RO+ compared with C- RO+ (p = 0.04), but not in the other two group comparisons (p-values of 0.09–0.63).
C2 and C5 were significantly (p = 0.031 and 0.020, respectively) and negatively correlated (r = -0.51 and -0.55, respectively) to CGRP in coughers (fig. 2a⇓ and b) but not in noncoughers (r = 0.28, p = 0.28 for C2; r = 0.29, p = 0.324 for C5; fig. 2c⇓ and d). Cough sensitivity did not relate to any other parameter in coughers and noncoughers. Cough sensitivity also did not correlate to CGRP, NKA, SP or to any BAL cellularity in the total group (p-values of 0.06–1.0).
DISCUSSION
The current authors have previously shown that in most children chronic cough was not associated with RO alone 20 and that airway neutrophilia is absent in children with RO 21. The present study adds to this information by showing that in the BAL of 40 children, CGRP, NKA and SP levels in children with chronic cough were not significantly different from those without cough. However, children with cough and biopsy-proven RO had significantly higher CGRP than children with reflux but without cough. Furthermore, CGRP, but not NKA or SP, related significantly to capsaicin cough sensitivity in children with chronic cough but not in those without cough.
The present study is the first to examine these neuropeptides in the airways of children with and without chronic cough. Neurogenic inflammatory mediators, particularly CGRP, have been implicated in the pathogenesis of chronic cough 12, 18. The present finding of CGRP in the BAL also being related to cough sensitivity in coughers but not in noncoughers is perhaps not surprising. In biopsy specimens, CGRP immunoreactivity has been found to be related to cough sensitivity in adults with chronic cough 18. This is likely to relate to the plasticity of the peripheral nervous system, with neurotrophins altering the pattern of innervation changes in inflammatory disease, as SP- and CGRP-immunoreactive nerves are sparse in normal human airways 27. CGRP-containing airway innervating nerves originate from the nodose-jugular ganglia (among other ganglia) 16, which is also the ganglia found to be central in the neurophysiology of the cough reflex 28. It is thus biologically possible that upregulation of these nerves causes a spill-over in the airways. CGRP can be released by noxious stimuli and plasma extravasation may occur 16, and thus CGRP in BAL may either occur from or lead to plasma extravasation. Increased pulmonary blood flow has been found to be associated with elevated levels of plasma CGRP 29, and high BAL levels may reflect circulating levels when airway disease is present, such as in circumstances when cough is reflective of airway disease. In an animal model, Daoui et al. 19 demonstrated that protein extravasation in the airways can be induced by hydrochloric acid infusion into the oesophagus, and that extravasation into the airways is mainly dependent on the release of tachykinins.
Using the animal model of acid GORD, two groups have demonstrated that oesophageal stimulation by hydrochloric acid causes neurogenic inflammation in the major airways 19, 30. In support of this, the present authors found that CGRP was significantly different between coughers and noncoughers within the group that also had RO. This suggests that RO is a necessary factor for this difference and that in the absence of RO, CGRP may be less important. The possible reasons for this finding are at least three-fold. First, the same sensory nerves supply the oesophagus and the airways via a long axon route. Canning 31 argues that gastric “refluxate can directly activate nociceptive nerves in the mucosa of the oesophagus, the pharynx, and the lower airways”. Secondly, afferents from the oesophagus in some way link up with and modify (upregulate) afferents from the airways, at either ganglionic or brainstem levels. Upregulation of the peripheral sensory neurones and brainstem regions has been described in animal studies 32, 33. A third possibility is that patients with RO also have aspiration, which in some cases, but not all, causes “chronic” cough. There are arguments for and against each of these possibilities, and further studies are required to evaluate these possibilities.
Ideally, CGRP and cough sensitivity should be re-measured upon the resolution of the cough in the present cohort of children. However, given that a general anaesthetic is necessary to obtain BAL in the present setting, this was not feasible and is thus one of the present study's shortfalls. Also, an association in no way proves “cause and effect” or “which occurred first”. Another possible limitation is that although international guidelines for BAL in children were utilised 34, it is unknown if neuropeptides in BAL obtained by nonbronchoscopic methods differ from those obtained using a bronchoscope. Furthermore, although a moderately strong correlation between cough sensitivity and CGRP was found in coughers but not in noncoughers, it was not demonstrated that CGRP was higher in the total cohort of coughers compared with noncoughers. However, this and other nonsignificant findings are possibly related to the small sample size.
Lack of the role of SP or NKA in the present study is consistent with other studies involving cough and the lower airways 17, 18. In the study by Forsythe et al. 17, CGRP but not NKA or SP induced BAL mast cells to release histamine in chronic coughers. Also, O'Connell et al. 18 described increased CGRP- but not SP-immunoreactive nerves in airway biopsies of adults with chronic cough.
Neurotrophins and VRs are important concepts in the pathophysiology of chronic cough, as described in biopsy specimens and animal models 13, 35. However, these markers were not measured in the present study, because in a previous study of 69 children (unpublished data), the present authors also found no difference in brain-derived neurotrophic factor or VR-1 mRNA in BAL cells between children with (n = 36) and without cough (n = 33). Also, Chaudhuri et al. 36 described that neurotrophins were not elevated in induced sputum or serum of adults with chronic persistent cough.
In a previous study 21, the present authors have also described a small but significantly reduced airway neutrophil percentage in children with RO without cough. This finding is also similar to a small (n = 11) study in adults with GORD and cough 37. Additionally, the present study's limitations with respect to other diagnostic modalities of GORD has been discussed in previous papers 20, 21 and thus is not repeated here. Similarly, the lack of association between cough and GORD in children was also the main discussion point in a previous paper 20. Cough is rarely solely attributed to RO in otherwise well children 20, 38, 39, which is in contrast to adults 40. Cough, symptoms of GORD and asthma are common; an association does not imply cause and effect 41, and the likelihood of these symptoms co-existing merely by chance is high 23.
A larger study, and one that includes follow-up of children with cough and bronchoalveolar lavage, is necessary to confirm the present findings. Nevertheless, the unique findings in the present study were two-fold. First, children with cough and biopsy-proven reflux oesophagitis had significantly higher calcitonin gene-related peptide levels in their bronchoalveolar lavage compared with children with reflux oesophagitis but without cough. This raises the question of plausible mechanisms of cough in reflux oesophagitis and it is likely that other factors are required to be present for reflux oesophagitis to elicit cough in humans. These factors are likely to include persistent neurogenic airway inflammation 12, and the present data support this. Second, calcitonin gene-related peptide, but not substance P or neurokinin A, related significantly to capsaicin cough sensitivity in children with chronic cough but not to those without cough. It was concluded that elevated calcitonin gene-related peptide, but not substance P or neurokinin A, is associated with chronic cough in children when oesophagitis coexists. Calcitonin gene-related peptide is likely to be an important neuropeptide in chronic cough when reflux oesophagitis coexists. The role of calcitonin gene-related peptide in bronchoalveolar lavage and serum deserves further evaluation.
Acknowledgments
The authors are grateful to M. DaSilva, the doctors and nurses of the Dept of Gastroenterology, Royal Children's Hospital, as well as the anaesthetists, in particular C. Beem, for their assistance in the present study. The authors are grateful to the children and parents who kindly participated in this study.
- Received November 18, 2006.
- Accepted January 9, 2007.
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