46 SAJSM vol 18 No.2 2006 Introduction Asthma and airway hyperresponsiveness (AHR) are more prevalent in elite athletes compared with sub-elite athletes and the general population. 18,35,46 Recent observations have suggested that high-intensity exercise and training might contribute to the development of asthma or AHR in athletes previously unaffected by these airway disorders. 7,8,20,24 The mechanisms explaining the increased prevalence of asthma and AHR remain to be determined. 5 However, research has suggested that exposure to specific local airway conditions and/or events during training and/or competition may initi- ate an airway inflammatory response. 23 Airway inflammation may influence the respiratory system through altering airway function 5 , and possibly inducing airway remodelling, similar to that which occurs in asthma. 8 This article discusses the recent research regarding asthma, AHR and airway inflammatory responses in athletes. Firstly, an overview of the prevalence of airway symptoms in athletes is provided. Secondly, research examining local airway conditions, events and inflammatory responses is discussed. Thirdly, research examining the possible remodelling of the airways in athletes is reviewed and finally, recommendations for future research in this area are provided. Prevalence of asthma and AHR in sport In the 1976 and 1980 Olympic Games, 9.7% and 8.5% of the Australian Olympic athletes had asthma, respectively. 12 In 1984, 26 (4.3%) of the 597 US Olympic team athletes had asthma, 41 (6.9%) had exercise-induced bronchospasm (EIB), while 42 (7%) had a history of exercise-induced bron- chial symptoms. 16 Weiler et al. 44 reported that 107 (15.3%) of the 699 US Olympic team athletes in the 1996 Summer Olympic Games had asthma. In 1998, the same authors ob- served a prevalence of 21.9% in 196 Winter Game Olympic athletes. 44 From these few studies it seems that the preva- lence of atopy-related symptoms is rising in elite athletes. The type of training (i.e. endurance, or speed and power) seems to influence the airway symptoms (asthma or AHR) in elite athletes. 17 The prevalence of atopic symptoms is high in endurance sports such as long-distance running (15.5 - 23.9%). 17 It is especially high in cold environment sports such as cross-country skiing (14.4 - 54.8%), 17 as well as in REvIEW ARTIClE Airway inflammatory and atopy-related responses in athletes A J McKune (DTech) l l Smith (PhD) Department of Sport and Physical Rehabilitation Sciences, Faculty of Health Sciences, Tshwane University of Technology, Pretoria Abstract The prevalence of asthma and airway hyperresponsive- ness (AHR) in highly trained endurance athletes is rising. The type of training (i.e. endurance, or speed and power) seems to influence the airway symptoms. High-intensity exercise and training might contribute to the development of asthma or AHR in athletes previously unaffected by these airway disorders. Repeated hyperventilation of un- conditioned air, as well as air containing irritants and/or al- lergens has been suggested to cause thermal, mechanical, or osmotic airway trauma resulting in damage to the airway epithelium. Subsequent airway inflammatory responses may be responsible for the development of atopy-related symptoms in endurance athletes such as those observed in asthma and AHR. Eosinophils and neutrophils are the inflammatory cells that have been frequently observed to be elevated in the airways of endurance athletes. The trafficking of these cells to the airways may possibly be regulated by TH2 cytokines that are expressed in the air- ways in response to epithelial cell damage. In addition, these airway inflammatory responses may lead to airway remodelling similar to that which occurs in asthma. The effect of the exercise challenge itself may initiate airway atopy-related and inflammatory responses in endurance athletes. While the literature seems to support the role of local airway conditions and/or events in inducing atopy-re- lated symptoms in athletes, it is proposed that alterations in the hormonal and/or cytokine milieu with intense com- petition and/or training may also play a role. CoRRESPoNDENCE: A J McKune Department of Sport and Physical Rehabilitation Sciences Tshwane University of Technology Private Bag X680 Pretoria 0001 Tel: 012-382 4442 Fax: 012-382 5801 E-mail: mckuneaj@tut.ac.za pg46-51.indd 46 6/28/06 1:47:43 PM SAJSM vol 18 No.2 2006 47 swimmers training indoors (13.4 - 44%). 17 For speed and power sports, including various athletes such as sprinters, football players and basketball players, the prevalence of asthma is slightly lower and usually ranges from 8% to 21%. 17,23 Effect of local airway conditions and events on airway atopy-related symptoms and inflammatory responses Dry, cold air Exercise hyperventilation with dry, cold air plays an important role in the development of airway symptoms in athletes. 23 It causes transient dehydration of the bronchial mucosa due to the low water content of the air, leading to a hyperosmolarity of the mucosal fluid of the airway surface lining, which may damage bronchial epithelial cells. 1,14 The hyperosmolarity of the mucosal fluid alters the osmotic gradient throughout the mucosa and sub-mucosa, resulting in the activation and de- granulation of mast cells in the sub-mucosa. Degranulation of these mast cells results in the release of pro-inflammatory mediators and the activation of cholinergic receptors. 23 This response causes airway smooth-muscle contraction and oedema which together reduce airway function, resulting in atopy-related airway symptoms. 1,4 It has recently been proposed that eosinophils in the airways become activated via a similar mechanism to that of the mast cells. 9 Research has indicated that the increased respiratory water loss during prolonged endurance exercise dehydrates the bronchial epithelium. The increased osmolality or osmotic challenge then indirectly triggers the release of eosinophil cationic protein (ECP) from eosinophils, 9 resulting in further epithelial cell damage, inflammatory responses and consequently airway atopy-related symptoms. 9 The inflammatory mediators that have been suggested to be implicated during these airway inflammatory responses include histamine, prostaglandins, leukotrienes, and chemotactic factors (chemokines), including IL-8 for neutrophils 5 and eotaxin for eosinophils. 33 In contrast to the studies mentioned above, Sue-Chu et al., 39 found that there were no significant differences in neutrophil or eosinophil counts/activation, but that other inflammatory markers significantly differed between athletes and controls. Examining the effect of hyperventilation of cold, dry air, these authors assessed the degree of macroscopic inflammation, the distribution of inflammatory cells, lymphocyte subtypes and markers of inflammatory cell activation in the airways of 30 adolescent cross-country skiers and 10 non-asthmatic, non-atopic controls. 39 The airways of these subjects were investigated using bronchoscopy, and inflammatory status was determined through analysing levels in bronchoalveolar lavage fluid (BALF). Nine (30%) of the skiers were atopic without allergy symptoms. Compared with controls there was a 3-fold increase in airway inflammation in the skiers. They also had greater total cell, percentage lymphocyte and mast cell counts compared with the controls. Neutrophil and eosinophil counts were not significantly different and ECP was not detected. Tumour necrosis factor (TNF)-α and myeloperoxidase were detected in 12 (40%) and 6 (20%) skiers, respectively. The authors concluded that cross-country skiers have a minor to moderate degree of macroscopic inflammation in the proximal airways compared with normal controls. 39 Recently, it was reported that exposure to cold air during exercise may up-regulate specific airway cytokine expression that may be responsible for inflammation and atopy-related conditions in the airways of athletes. 7 Using an animal model (exercising horses) and a random crossover design, BALF was obtained after 15 minutes of submaximal exercise while breathing room temperature or subfreezing air. BALF total and differential nucleated cell counts and relative cytokine mRNA expression in BALF nucleated cells were determined. There were no differences in total or differential cell concentrations between the room temperature and cold air conditions. However, TH2 cytokines IL-4, IL-5, and IL-10 were significantly upregulated after cold air exercise 12-, 9-, and 10-fold respectively compared with warm air exercise. In addition, other cytokines, IL-2 and IL-6, were upregulated to a lesser extent (6- and 3-fold respectively) or not at all (IL-1, IL-8, IFN-α, and TNF-α). The authors argued that exercising while breathing cold dry air induces an overall cytokine pattern in the airways that is predominantly a TH2 profile. 7 TH2 cytokines, in support of the underlying theme of this review, are a characteristic of the systemic immune profile found in allergies and asthma where they regulate the production of IgE antibodies as well as the infiltration of inflammatory cells such as neutrophils and eosinophils. 43 Allergens Runners, and cyclists are exposed to many pollen allergens in spring and summer. 42 When the ventilation level exceeds about 30 l/min there is a shift from nose breathing to com- bined mouth and nasal breathing. 2 This shift results in a greater deposition of airborne allergens and other inhaled particles in the lower airways. 19 Research has demonstrat- ed that symptoms of asthma may develop in athletes who are repeatedly and strongly exposed to pollen allergens. 32 This author suggested that an allergen overload in the air- ways could lead to an inflammatory process through an IgE- dependent mechanism. In other words, the high number of allergens within the airways could increase the possibility that IgE attached to mast cells become cross-linked. This in turn would lead to an acute inflammatory response through mast cell degranulation and the release of airway pro-inflam- matory mediators. 23 Pollutants The quality of the air inhaled by athletes during training or even at rest may contribute to the development of AHR. A relationship has been shown between pollutants such as, pg46-51.indd 47 6/28/06 1:47:43 PM 48 SAJSM vol 18 No.2 2006 ozone (O3), sulphur dioxide (SO2), nitrogen dioxide (NO2), exercise and the development of atopy-related respiratory symptoms. 23 Studies have demonstrated that the combina- tion of exercise and exposure to pollutants can cause a sig- nificant increase in bronchoconstriction and a reduction in ventilatory flow when compared with pollution exposure at rest. 13,27 Swimmers, chlorine and AHR Research has found an abnormally high prevalence of AHR among elite swimmers. 31 Studies have shown that swimmers are chronically exposed to chemical compounds used as wa- ter disinfectants. 10 These disinfectants include chlorine and its derivatives, chloramines and chloroform, which irritate the airways, causing inflammation and oedema of mucous mem- branes. 31 Research has shown that during a 2-hour training period, a swimmer may be exposed to an amount of chlorine that exceeds the US recommendation for a worker with 8-hour exposure. 10 During training and competition, highly trained swimmers inhale large amounts of air that floats just above the water surface, and they may possibly micro-aspirate contaminated water into the trachea and bronchi. 16 Repeated exposure to chlorine gas has been shown to cause asthma symptoms, airflow obstruction, and increased bronchial responsiveness. 6 In these cases, the histological analysis of the bronchial mucosa has shown a thickened basement membrane, and eosinophilic inflammation. 6 A long-term effect of swimming training on airway inflammation was reported by Helenius et al. 20 These authors investigated respiratory symptoms, increased bronchial responsiveness, and signs of airway inflammation in 29 elite swimmers and 19 healthy controls. The subjects answered a questionnaire and were interviewed for respiratory symptoms. Lung volumes were measured and bronchial responsiveness was assessed by a histamine challenge test. Induced sputum was also collected. Fourteen (48%) of the swimmers and 3 (16%) of the control subjects showed significantly increased bronchial responsiveness. The sputum cell differential counts of eosinophils and neutrophils of swimmers were significantly higher than those of controls. Eosinophilia (sputum differential eosinophil count of > 4%) was observed in 6 (21%) of the swimmers and in none of the controls. Symptomatic swimmers had significantly more sputum eosinophils than did those who were symptom-free. The concentrations of sputum eosinophil peroxidase (EPO) and human neutrophil lipocalin (HNL) were significantly higher in swimmers than in control subjects. The authors concluded that long-term and repeated exposure to chlorine compounds in swimming pools during training and competition may contribute to the increased occurrence of bronchial hyperresponsiveness and airway inflammation in swimmers. 20 Summary of research examining airway inflamma- tion in athletes Surprisingly, there are few studies that have addressed the issue of exercise-induced airway inflammatory responses in athletes. In addition to the studies already discussed, a summary of the majority of research available is provided in Table I. Overall, the results indicate that an increase in poly- morphonuclear neutrophil (PMN) cells is found in most stud- ies irrespective of the sample type or sport activity, while el- evated eosinophil and lymphocyte counts are found mainly in swimmers and skiers. It has been suggested that the eleva- tion in PMNs may be a direct consequence of the endurance exercise, while the elevation in the other cell types may de- pend on exposure to environmental factors such as chlorine or cold, dry air. 4 However, this statement is highly speculative and requires additional research. Importantly, the only study examining an underlying mechanism which may explain ex- ercise-induced airway inflammatory responses and the de- velopment of atopy-related symptoms has been performed using an animal model. 8 The results of this study have im- portant implications for understanding the high prevalence of atopy-related airway symptoms in athletes. However, further research on humans is required to verify the findings. limited airway inflammatory responses in athletes In contrast to the previous discussion regarding airway in- flammatory responses inducing atopy-related symptoms in athletes, there is an argument that the airway inflammatory responses are not maladaptive. Research has suggested that similar to systemic compartments, inflammation in the airways is tightly regulated. Recently, it has been argued that the concept of limited systemic inflammation in athletes may also be applicable to the airways. 4 Although inflamma- tory cells are recruited to the airways, it has been shown that they do not always become activated. 3,25 As an example, in swimmers there was significant neutrophil infiltration into the airways, but with no evidence of inflammatory cell activation at rest or after exercise. Specifically, neutrophil elastase con- centration in sputum was low at all times. 28 Preliminary data also suggested that an increase in airway inflammatory cells is not associated with enhanced bronchial responsiveness or functional impairment in non- asthmatic athletes. 4 Interestingly, research has shown that frequent episodes of exercise hyperventilation may even reduce the susceptibility to bronchoconstriction in well- trained individuals. Specifically, well-trained runners showed blunted responses to metacholine compared with sedentary controls. 4 Therefore, there may be an inhibitory pathway that prevents or reduces airway inflammatory cell activation and inflammation; however, this has not been identified and further research is required. 4 Similarly, the questions regarding whether exercise affects the airway and systemic compartments in the same manner, and the possibility that pg46-51.indd 48 6/28/06 1:47:44 PM SAJSM vol 18 No.2 2006 49 training may also cause positive adaptations at the airway level, have not been answered. 4 Airway remodelling Airway remodelling has been shown to occur in atopic dis- ease such as asthma. The process is initiated through chronic airway inflammation and is associated with a contin- ual or abnormal healing process resulting in airway structural alterations. 23 This remodelling process is characterised by various changes such as hypertrophy and hyperplasia of air- way smooth muscle, increased numbers of mucous glands, thickening of the reticular basement membrane from colla- gen deposition, blood vessel proliferation, and alterations of the extracellular matrix. 26 These, in turn, lead to airway wall thickening and a permanent reduction in airway calibre with a detrimental effect on respiration. 23 Airway remodelling in athletes There is little information available that links exercise hyper- ventilation with the induction of structural and/or physiologi- cal changes in the airways. 23 Some preliminary evidence of airway remodelling has been demonstrated in bronchial biop- sies from cross-country skiers. 21 Karjalainen et al. 21 measured mucosal inflammatory cell infiltration and tenascin expression (a marker of tissue injury) in the sub-epithelial basement membrane in endobronchial biopsy specimens of the proximal airways. The subject populations included 40 elite, competitive skiers without a diagnosis of asthma, 12 subjects (non-athletes) with mild asthma, and 12 healthy controls (non-athletes). Skiers had significantly higher lymphocyte (+43-fold), macrophage (+26- fold) and eosinophil (+2-fold) counts compared with healthy controls. Patients with mild asthma also had significantly TAblE I. Studies on airway inflammatory responses to exercise Author, year (ref) Athletes tested Methods Main results Cross-country skiers Sue-Chu et al. 1999 39 Cross-country skiers BALF ↑ total cell, lymphocyte, and mast cell counts; markers of inflammatory cell activation not ↑ Karjalainen et al. 2000 21 Cross-country skiers BB Compared with controls, ↑ T-lymphocytes (43-fold), macrophages (26-fold), eosinophils (2-fold), PMN (2-fold) in bronchial mucosa. No relationship between airway cells and BHR, symptoms or atopy Sue-Chu et al. 2000 38 Cross-country skiers BALF, BB No change in airway inflammation after budesonide treatment after inhaled steroid (800 µg/day, over 20 weeks), variable effect on symptoms treatment Swimmers Helenius et al. 1998 18 Elite swimmers Induced sputum ↑ PMN and eosinophil differential counts compared with controls; ↑ inflammatory markers; eosinophils = 4% in 21% of swimmers Helenius et al. 2002 15 Elite swimmers 5-year follow-up Induced sputum Eosinophil differential counts ↑ over time in athletes continuing competitions, decreased in athletes who quit Morici et al. 2001 28 Swimmers training outdoors Induced sputum Baseline: ↑ PMN differential counts (swimmers 44 ± 22%; sedentary controls: 10 ± 6%), no ↑ in eosinophils; 5-km swimming in outdoor pool: no change; 5-km swimming in the sea (hypertonic environment): slight ↑ in eosinophils Boulet et al. 2005 5 Swimmers training indoors Induced sputum Baseline: no ↑ in airway inflammation in high-level swimmers; short- term high-intensity training (1 h) associated with an ↑ in airway neutrophils in hyperresponsive swimmers Runners Muns 1993 29 Half-marathon runners Nasal lavage Post-half-marathon: immediately after ↑ PMN (3-fold); 24 h after remained elevated (1.6-fold) compared with pre-race. ↓ in % phagocy- tosing PMNs and function pre-race, immediately after and after 24 h Muns et al. 1996 30 Marathon runners Nasal lavage Post-marathon: immediately after ↑ PMN (2.7-fold); remained elevated up to 3 days after. ↑ neutrophil chemotactic activity (2.5-fold) immedi- ately after the race Bonsignore et al. 2001 3 Marathon runners Induced sputum Baseline: ↑ PMN differential counts (79 ± 9%); post-marathon: further ↑ PMN (91 ± 4% of total cells) Wetter et al. 2002 45 Endurance athletes with AHR Induced sputum Baseline: PMN differential counts: 37% (range 13 - 49, no control sam- ples); post-exercise: unchanged after placebo or anti-inflammatory drugs Boulet et al. 2005 5 Marathon runners Induced sputum Baseline: no ↑ in airway inflammation in high-level runners; short-term high-intensity training (1 h) associated with no ↑ in airway inflammation Davis et al. 2005 7 Horses BALF Post-15 minutes submaximal exercise. ↑ TH2 cytokine (IL-4, IL-5, IL-10) expression after cold air exercise compared with warm-air exercise BALF = bronchoalveolar lavage fluid; BB bronchial biopsy; PMN = polymorphonuclear neutrophil; BHR = bronchial hyper-reactivity. pg46-51.indd 49 6/28/06 1:47:44 PM 50 SAJSM vol 18 No.2 2006 higher lymphocyte (+70-fold), macrophage (+63-fold) and eosinophil (+8-fold) than the controls. In the skiers, neutrophil counts were more than 2-fold greater than in asthmatic subjects. Tenascin expression was increased in skiers and asthmatic subjects compared with controls. However, the bronchial biopsy findings did not correlate with AHR, atopy or symptoms of asthma. 21 These authors concluded that prolonged repeated exposure of the airways to inadequately conditioned air may induce inflammation and remodelling in competitive skiers. 21 It is possible that airway remodelling without airway symptoms may represent a form of adaptation to exercise hyperventilation within the airways. In other words, this may be 'healthy' remodelling rather than maladaptive. Further research is required to test this hypothesis. However, a recent study, using a canine model, demonstrated that repeated hyperventilation of cold air during exercise may in fact cause airway inflammation and remodelling, leading to asthma-like symptoms. 8 Daily, repeated hyperventilation caused the influx of eosinophils, neutrophils and mast cells into the airways. Cationic proteins (i.e. ECP) released by the eosinophils were suggested to be partly responsible for airway epithelial cell and connective tissue injury, which was still not healed after 24 hours. This repeated exposure resulted in stratified squamous epithelium (squamous metaplasia), replacing the normal ciliated epithelium. There was also an increase in the thickness of the airway lamina propia (sub-mucosal area) as well as goblet cell hyperplasia, possibly due to oedema relating to damage and an inflammatory response. The increase in squamous epithelium suggested that airway repair and remodelling was taking place. 8 The loss of airway epithelial cells was shown to be detrimental to normal airway function. These cells are an important source of prostaglandin E2 (PGE2), which serves to inhibit cholinergic neurotransmission, smooth-muscle contraction, and mast cell degranulation. 22 A loss of airway ciliated epithelium and an increase in the thickness of the airway lamina propia result in impaired mucociliary clearance and accumulation of intraluminal debris, leading to the development of airway obstruction. These factors may all play a role in the pathological atopy-related responses of the airways. Davis et al. 8 concluded that their results suggested that repeated exercise in cold weather could provoke changes in the airway morphology, leading to many of the common symptoms of asthma in athletes who did not previously suffer from this respiratory condition. Although the evidence from this study is convincing, further research is required, specifically using human athletes. Conclusions and recommendations for future research This review has provided a brief discussion of factors that may explain the development of pathological atopy-related responses in athletes. The literature suggests that hyper- ventilation during exercise, combined with exposure to cold air and/or to a mixture of allergens and pollutants, induces airway inflammatory responses and possibly airway remod- elling which may be responsible for the development of asthma or AHR in elite endurance athletes. 17 The majority of the research has reported differences in inflammatory cell recruitment or activation in the airways of elite endurance athletes, at baseline or after exercise intervention, compared with controls. However, only recently have there been re- ports of the possible underlying mechanisms that explain the regulation of airway inflammatory responses 7 and how these airway inflammatory responses may result in pathological air- way remodelling. 8 Importantly, these two studies used animal models and future research should be performed to validate the proposed mechanisms in human studies. Finally, future research should examine the effect of the exercise challenge itself on airway atopy-related and inflammatory responses in elite endurance athletes. While the literature seems to support the role of local airway conditions and/or events in inducing atopy-related symptoms in athletes, various researchers have proposed that alterations in the hormonal and/or cytokine milieu with intense competition and/or training may also play a role. 37,40 Specifically, Susuki et al. 41 have shown that the circulating lymphocyte population is biased toward TH2 profile of cytokine secretion after exercise. This bias was related to the concurrent release of glucocorticoids during exercise, which promote a shift from a TH1 to TH2 cytokine profile. 11 Recently, Smith 36,37 proposed that the increased incidence of atopy- related symptoms associated with strenuous exercise may be due to an altered focus of immune function. Specifically, it was hypothesised that repetitive tissue trauma sustained during strenuous exercise training induces a systemic TH2 cytokine profile. The consequence of the bias towards a TH2 profile is the up-regulation of humoral immunity (HI). This implies the proliferation and differentiation of B-cells into antibody- secreting plasma B-cells; immunoglobulin (Ig) class (isotype) switching from IgM to IgG1-4, IgA or, in support of the argument in this review, IgE; as well as eosinophil migration from the bone marrow to, and activation in, the airways. 33,34 As discussed earlier in this review, IgE and eosinophils are crucial factors involved in promoting the airway inflammatory responses that occur in allergies and asthma. From the above discussion it is feasible to suggest that, in addition to local airway conditions and events, the exercise challenge itself may play a role in influencing atopy-related and inflammatory responses in the airways. Research has yet to determine the exact impact of local and systemic factors on the airway responses of elite endurance athletes and hence, considerably more research is required in this area. pg46-51.indd 50 6/28/06 1:47:45 PM SAJSM vol 18 No.2 2006 51 RefeRences 1. 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