Inducible laryngeal obstruction: an official joint European Respiratory Society and European Laryngological Society statement

Clinical features

A secure diagnosis of ILO is dependent on the presence of compatible clinical features, precipitated by exposure to an inducer or trigger and with concurrent objective verification of laryngeal obstruction, ideally by direct laryngoscopic examination [4].

Typical clinical features include wheeze, dyspnoea and cough, and these symptoms are highly variable and evanescent. In most cases, individuals with ILO will exhibit inspiratory breathing difficulties, although a pure expiratory form of ILO has been described [5].

When exercise is the inducer, the timing of symptom onset is informative. Symptoms of exercise-induced laryngeal obstruction (EILO) are typically maximal during strenuous exercise, in contrast to exercise-induced bronchoconstriction, in which symptoms typically can peak up to 20 min after exercise cessation. Dyspnoea caused by EILO can be accompanied by coarse or high-pitched inspiratory breath sounds, sometimes progressing to clear-cut stridor, and may be associated with severe respiratory distress, hyperpnoea and/or panic reactions, evolving in parallel with increasing ventilatory requirements throughout the exercise session. The term exercise-induced inspiratory symptoms has been introduced [2]; however, patients suffering from EILO are sometimes unable to attribute respiratory symptoms to a specific phase of the breathing cycle, particularly when interviewed at a first consultation. Several studies indicate that self-reported symptoms are poor predictors of EILO [3, 6, 7].

There are several symptom questionnaires that attempt to detect ILO [8–10]. These focus on the glottic component of ILO, with the exception of the dyspnoea index [9], and have yet to be comprehensively validated in a multicentre context. However, questionnaires show promise as diagnostic screening tools, while providing a structured description of symptoms.

Laryngoscopic technique

We have described previously how to perform a laryngoscopic examination and standards with regard to the key findings that should be reported in all cases [4]. Specifically, the change in laryngeal features from baseline to the point of maximal obstruction should be described. Furthermore, whether the obstruction to airflow is at a glottic or supraglottic level should be detailed [3, 6, 11–13]. In cases of combined supraglottic and glottic involvement, the two levels of obstruction may not be co-temporal throughout the attack. For multilevel obstruction, the sequence of events should be described if possible. It is helpful to record the laryngeal movement continuously for later analysis.

The degree of laryngeal obstruction can vary from mild to severe [12], with near-complete closure in some cases [1]. There is currently no gold-standard validated scoring system that differentiates normal from abnormal responses. Proposed methods for image quantification of the degree of obstruction have included measurement of laryngeal anterior–posterior (A–P) diameter [14–16] and measurement of anterior glottic angle [15]. Continuous recordings have used subjective reviewer grading estimates of obstruction [12] and computerised calculations relative to measured change in the glottic or supraglottic aperture [17].

Some authors have hypothesised that introducing a laryngoscope into the nasopharyngeal space and/or applying local anaesthetics to the nasal cavity may affect laryngeal reflexes and thus confound the results. Research is needed to address this issue, but there is currently no published evidence to support this notion.

Inducers of laryngeal obstruction

The most common inducers of laryngeal obstruction are exercise, irritants and emotional stress. An inducer in this context is defined by its ability to trigger sufficient narrowing of the laryngeal space to cause breathing difficulties and a laryngoscopic image compatible with laryngeal obstruction to airflow. The task force acknowledges that to a large extent, the latter is subjective. Therefore, while awaiting objective assessment of this feature (e.g. accurate measurements, validated scoring systems or pressure change measurements) the method by which this assessment was performed should be detailed.

Exercise

Where exercise is an inducer, laboratory provocation studies attempt to simulate the real-life (i.e. in the field) scenario, but most commonly employ an indoor treadmill [11, 17, 18], stationary bicycle [19] or, very occasionally, other exercise modalities [20].

Exercise protocols vary, but all aim to exercise subjects until symptoms are elicited and/or peak exercise capacity has been achieved. EILO typically occurs at high levels of ventilation [13], which entails that a maximal exercise test protocol must be employed. These simulation methods have been applied in large studies of symptomatic individuals and in symptom-negative controls [2, 3, 6, 21], but their between-test reliability and validity remain to be established. Crucial in this context is the ability of the test set-up to facilitate sustained maximal efforts (beyond the aerobic threshold) for as long as necessary to induce symptoms. This might be more easily achieved if using free running or other ‘in the field’ techniques, as has been addressed in studies of exercise induced asthma [22]; however, this scenario has not been studied in relation to EILO.

The continuous laryngoscopy during exercise (CLE) test uses a flexible nasolaryngoscope fixed to a head apparatus, allowing real-time visualisation of the larynx throughout the study (figure 2) [11]. The CLE test has now been used in multiple research studies and provides recorded images detailing the temporal change of laryngeal obstruction, as it occurs during exercise [13]. The CLE test has helped establish the fact that EILO commonly arises from supraglottic (i.e. aryepiglottic fold) obstruction; however, in some cases it may be a pure glottic (i.e. vocal cord) phenomenon, or both can occur [2]. The relationship between laboratory EILO and EILO “in the field” is yet to be studied, and anecdotally, many athletes report heightened symptoms in the competitive environment (e.g. potential anxiety and physicality of competitive sporting events).

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FIGURE 2

Continuous laryngoscopy during exercise. The laryngoscope is secured to a headset via a facemask. The screen shows real-time images of the patient, her larynx and cardiopulmonary exercise data while running.

Irritants

A retrospective review included the first description of “irritant”-associated vocal cord dysfunction [23]. A variety of breathing and other problems were temporally associated with a single occupational (n=10) or environmental (n=1) exposure, based upon history alone, with no environmental exposure analysis. Inclusion required the patient's perception of a “gas smoke, fume, vapour, mist or dust”. In several cases “…the exact offending agent(s) could not be determined…” nor was a physical “irritant” or injury effect documented, yet there was a presumptive attribution to “irritant inhalational injury”. A broad range of irritants have been described in case reports and case series, including odours [10, 24, 25], sleep [26], stress [10], cold air [10], gastrolaryngeal reflux [27], environmental and occupational exposures [28–30], wood dust [31] and chemicals [29, 32, 33]. The causal mechanism of irritant ILO is unknown. It is unclear if irritant ILO is a direct response to the irritant stimulus itself, e.g. via mucosal inflammatory reactions, or related to altered reflex sensitivity, and to what extent psychological factors contribute; highlighting the lack of evidence in the field.

Use of surrogate inducers

Substitute (surrogate) methods for the inducer have been used to precipitate ILO. Specifically, the use of methacholine [7, 34], mannitol [7] and histamine [14, 35, 36] as laryngeal provocation agents has been studied, using standard bronchoprovocation test methodologies, but with a focus on the inspiratory component of the flow–volume loop on spirometric measurements.

The relationship between bronchoprovocation testing and ILO is complex and incompletely understood. Indeed, patients with laryngoscopic evidence of ILO may have ILO during methacholine challenge, as well as with saline placebo [37]. Many authors have concluded that methacholine challenge is of little help in differentiating EILO from asthma, and indeed, the two conditions may coexist [37–40]. In addition, it remains unclear whether substitute inducers and self-induction are comparable to the laryngeal response during a typical “symptomatic” episode.

Eucapnic voluntary hyperpnoea has been used with direct laryngoscopic visualisation [41], and can induce glottic as well as supraglottic obstruction. However, the sensitivity and specificity of these findings remain unclear, and in one study the authors commented that poor visualisation of the larynx limited the utility of this technique [41].

Use of surrogate means to detect laryngeal obstruction

Diagnostic methods other than laryngoscopy have been evaluated in the diagnosis of ILO; most often full flow–volume measurement with spirometry. Patients with ILO [1] typically have a normal flow–volume loop while asymptomatic; however, during a spontaneous episode a variable extrathoracic obstruction pattern can be present, i.e. with attenuation in the inspiratory flow compared to expiratory flow [1, 5, 39, 40, 42–44]. There are several causes of a blunted or truncated inspiratory flow–volume curve, including inadequate instruction, suboptimal effort or inability to perform the procedure, as well as other diseases such as diaphragm weakness, fixed large airway obstruction and any cause of reduced lung compliance [37]. It is therefore not surprising that the diagnostic precision of spirometric assessment of ILO is poor [39, 43]. One study evaluated the flow–volume loop before and after exercise, and found no correlation with laryngoscopy-documented ILO. The authors concluded that exercise-induced laryngeal obstruction cannot be diagnosed or excluded by physician-evaluated pre- and post-exercise flow–volume loops [45]. Similarly, assessment of intra-exercise tidal flow–volume relationships has not been systematically validated in a context of EILO diagnostics, presently precluding evidence-based use of these measures. Finally, flow–volume loops cannot differentiate supraglottic from glottic ILO, distinctions that have a bearing on choice of treatment. Thus, the use of flow–volume loops (resting and intra-exercise) as diagnostic tool in ILO needs to be further explored in future studies.

Forced oscillation techniques may be a diagnostic or screening tool for ILO [46–49]; however, the sensitivity and specificity of these methods are insufficiently described and more research is needed.

Computed tomography, with three-dimensional images of laryngeal obstructions, has been reported to identify ILO in a cohort of patients with difficult-to-treat asthma [50]. Limitations of this technique include the absence of documentation of a symptomatic spontaneous or provoked episode during testing, need for supine positioning and brief data acquisition window, due to concerns about radiation exposure.

Mechanical insufficiency

It is likely that mechanical factors, based upon pressure change across the laryngeal inlet, are relevant in ILO triggered by exercise. The Bernoulli principle states that increasing airflow through a tube creates increasing negative pressures within that tube [56]. For the laryngeal aperture, the flow rate at which this will occur is determined by the area and configuration of the laryngeal opening and external support from surrounding structures. Thus, EILO may be explained by laxity of muscles, ligaments or the laryngeal cartilages. Of possible interest in this context is a relationship between congenital laryngomalacia (CLM) and EILO as proposed by Smith et al. [57] in 1995, and a link from CLM to adolescent EILO proposed in a small study by Hilland et al. [58] in 2016. Certainly, there are no studies to date that indicate that EILO in general can be explained simply by CLM; however, these two studies underline that laryngeal structure does seem to be relevant for EILO and that a history of CLM may be of relevance in some subgroups.

The posterior cricoarytenoid (PCA) muscle is the principal laryngeal abductor. Thus, a malfunctioning PCA muscle may lead to a smaller laryngeal aperture, possibly to a size below a critical level during high airflow states (i.e. exercise) [59].

The presentation of EILO is most frequently described in early adolescence and more often in females [2, 3, 21, 37]. The aryepiglottic folds and the cuneiform tubercles make the supraglottic opening relatively narrower in adolescents than in adults [60, 61]. There is no sex difference in the relative size of the prepubertal laryngeal aperture, while significant sex differences are described to occur throughout the pubertal growth spurt [61, 62]. These factors may all contribute to the age and sex distribution of the EILO epidemiology. However, changes with time and growth or differences as regards exercise habits, symptom awareness or other factors could also be involved and this needs to be explored in studies.

Neural dysfunction

Neural reflex control is important for adequate laryngeal function in relation to respiration, swallowing and protection against aspiration. The hypothesis behind reflex-associated VCD is that direct stimulation of sensory nerve endings in the respiratory tract may induce a protective reflex, triggering laryngeal closure [23]. Mechanical or chemical stimulation of the supraglottic mucosa or direct stimulation of the superior laryngeal nerve may activate the laryngeal adductor reflex to protect the airway from aspiration or asphyxiation [63].

As discussed in detail below, gastro-oesophageal reflux (GOR; both acidic and nonacidic) may sensitise the glottal closure reflex [34, 64]. However, paradoxically, evaluating laryngeal sensitivity with direct mechanical stimulation has indicated reduced laryngeal sensitivity in the presence of reflux [65]. This may explain anecdotal reports of proton-pump inhibitors improving reflux, but not VCD [52]. Furthermore, and again anecdotally, a cold climate reduces exercise tolerance in patients with EILO, and inspiratory stridor is more prevalent in outdoor (8.3%) compared to indoor athletes (2.5%) [40]. Collectively, these observations indicate that environmental factors might be involved in the aetiology of EILO; however, mechanisms remain unknown and should be addressed in future studies.

Psychological contribution

Several studies indicate the importance of considering a psychological contribution in ILO [51, 66, 67]. Specifically, in a sample of 171 cases with paradoxical vocal cord motion, only 7% did not have a psychiatric diagnosis [51]. Others have claimed that VCD represents the physical manifestation of underlying psychological problems [68]. These statements have been disputed, with the authors arguing that the tendency for panic observed in some patients is caused by the choking feeling of laryngeal collapse during heavy exercise, rather than being the cause of EILO [2]. These complex issues need to be addressed in properly designed studies.

Asthma

ILO has long been recognised to mimic asthma [1], but is increasingly recognised to coexist with asthma. The contribution of each to a given episode of respiratory distress may be difficult to determine.

The use of standard effort-dependent lung function methods for diagnosis of comorbid asthma requires reliable, consistent and reproducible results. However, patients with ILO have been reported to have difficulty performing reproducible maximal flow–volume loops [29, 33]. If the vital capacity is reduced due to inducible laryngeal inspiratory obstruction, the forced expiratory volume in 1 s (FEV₁) is also likely to be reduced, potentially leading to an erroneous diagnosis of asthma, although the FEV₁/forced vital capacity ratio may be normal and suggestive of a restrictive, not an obstructive, pattern. The flow–volume loop in a symptomatic patient with confirmed inspiratory and expiratory ILO, and unequivocally excluded asthma, can still demonstrate a concave reduction in expiratory flow, mimicking asthma. Moreover, if only the percentage reduction in FEV₁ data is reviewed in interpretation of bronchoprovocation studies, such as a methacholine challenge, a misdiagnosis of asthma can be made.

Bronchoconstriction may itself induce laryngeal obstruction, which presents a significant barrier to the robust scientific study of asthma as a comorbidity of ILO. Use of endoscopic photography in normal subjects [14] demonstrated true vocal fold adduction on inspiration and expiration with reduced glottic area during histamine-induced bronchoconstriction measured with spirometry. Thereafter, 34 patients with obstructive lung disease of varying severity on spirometry were examined using endoscopic photography and calculation of glottic area referenced to a separately established constant A–P glottis diameter [69]. Results showed that glottic area (due to adduction of the true vocal folds) decreased proportionally to the decrease in FEV₁ on inspiration and expiration, and was more pronounced on expiration.

Future investigations should utilise objective diagnostic methodology to explore the possible associations between ILO and asthma, and to elaborate on these rather old studies. However, two important practical points can be extracted from the available literature: every effort should be made to diagnose asthma objectively [70], and secondly; in known asthmatics, it should not be assumed that all episodes of respiratory distress are due to asthma.

Reflux

Objective studies using manometry or impedance in patients with documented ILO have not been conducted to confirm that GOR episodes occur in a temporal relationship to symptomatic ILO episodes [71]. Patients with documented GOR and cough had significantly reduced laryngopharyngeal sensitivity, defined as the lowest air pressure required to induce the laryngeal adductor reflex, a transient episode of true vocal cord adduction. In short, the laryngeal adductor reflex threshold was higher in the GOR group. Laryngopharyngeal sensitivity was then compared before and after laryngopharyngeal infusions of normal saline and 0.1 N hydrogen chloride on separate days. In normal subjects the laryngopharyngeal sensitivity threshold for the laryngeal adductor reflex was significantly raised with acid, but not saline infusion, suggesting that small amounts of acid infusion into the laryngopharynx significantly impaired sensory integrity. A follow-up study [72] confirmed that the laryngopharyngeal sensitivity threshold for the laryngeal adductor reflex was elevated in GOR. Nonetheless, a smaller volume of infusion directly into the laryngopharynx was required to trigger the laryngeal adductor reflex in patients with GOR than in normal controls.

Nasal disease

Sinus computed tomography in patients with laryngoscopy-confirmed ILO was compared to patients presenting to the emergency room with acute asthma, patients with nonacute asthma and nonasthmatic controls [73]. There was extensive sinusitis in 23 of 74 acute asthmatics, five of 29 nonacute asthmatics, two of 59 controls and none of 13 ILO patients. The authors concluded that patients with ILO could be distinguished from asthma by sinus computed tomography, but the evidence is inconclusive, and in any event, the two frequently coexist.

General approach

There are currently no published randomised controlled treatment trials. Even anecdotal reports frequently do not adequately confirm the diagnostic work-up and the outcome measure(s) that were applied, or characterise the type or severity of ILO. Multiple and often vaguely described management steps and a multitude of anecdotal reports complicate an overall interpretation. There is thus an urgent need for systematic and focused randomised controlled trials, with inclusion criteria as well as outcome assessment performed objectively. Video-recorded verification of laryngeal obstruction may be of value, not only as a diagnostic tool, but also as a therapeutic measure. Simply observing their own malfunctioning larynx has been reported to be of help in a majority of patients with mild or moderate disease [55]. Furthermore, simply identifying the problem may prevent inappropriate escalation of asthma therapy [74].

Medical treatment

Surgical treatment