Understanding dyspnoea by its language

Chest tightness

“Chest tightness” is frequently reported by asthmatic patients. At the Hering-Breuer Centenary Symposium, London, UK, Petit 9 reported that the sensation of chest tightness induced by acute bronchoconstriction receded after vagal blockade. During acute bronchoconstriction, chest tightness may arise from the stimulation of sensory receptors within the lungs mediated through vagal and autonomic pathways. Slowly adapting receptors are excited by contraction of airway smooth muscle; rapidly adapting (irritant) receptors and C-fibres may respond to local inflammation of the airways 10. Support for this hypothesis comes from the fact that airway anaesthesia with lidocaine reduces the sensations of chest tightness associated with histamine-induced bronchoconstriction, leading to the conclusion that vagal activity contributes to the sensation of chest tightness 11.

Work/effort

Descriptors comprised in the cluster “work/effort” are selected as common for most diagnoses and characterise several clinical conditions 1. Regardless of the specific disorder, work/effort intensifies during exercise. The increase in motor command to ventilatory muscles relayed by interneurons high in the central nervous system to the sensory cortex (corollary discharge) can be perceived as a sensation of effort 12–15. The intensity of the motor command alone, or in combination with the generation of force and contraction of the respiratory muscles, may be consciously appreciated as difficult breathing 16. Therefore, the respiratory muscles are important to the experience of dyspnoea. The score of effort decreases with assisted ventilation as compared with spontaneous breathing, during methacholine (MCh)-induced bronchoconstriction 17.

Unrewarded inspiration

The central motor command output to the sensory cortex (the corollary discharge) is modulated by a peripheral feedback from a host of respiratory mechanoreceptors that provide precise kinesthetic information about inspiratory muscle displacement (muscle spindles), tension development (Golgi tendon organs), changes in respired volume and flow, and airway calibre (vagal lung and airway mechanoreceptors) 16. The relative contribution of these receptors to the perception of intensity and quality of respiratory sensations in induced bronchoconstriction and hyperinflation has only recently been elucidated. In patients with low cervical quadriplegia, the quality and intensity of dyspnoea during MCh-induced bronchoconstriction and dynamic hyperinflation were similar to that in asthma at maximal response and not altered by extensive chest wall de-afferentation 18. The disparity between respiratory motor output and the mechanical response of the system is thought to play a major role in the increased perception of exercise dyspnoea in patients with COPD 19–21 and interstitial lung disorders (ILD) 22. Reduced lung volumes and increased respiratory drive account for the imbalance between the increased central output and the probable reduced instantaneous peripheral feedback from the lung and chest wall 19–22.

Rapid breathing

When healthy subjects exercise with external thoracic restriction, they frequently identify inspiratory difficulty as “rapid” and “shallow” as appropriate descriptors of their respiratory discomfort 1, 2, 5, 23. Rapid breathing also characterises the exercise response in patients with ILD 22. The increased respiratory drive results in increased respiratory frequency because of inadequate lung distensibility. Vagal afferents are potentially implicated. Chest compression and lung deflation could potentially reduce the input from stretch receptors with resultant tachypnoea, and simultaneously increase the input of rapidly adapting vagal receptors, which increase respiratory drive and ventilation, thus contributing to dyspnoea 24, 25.

Air hunger

Hypercapnia drives breathing and, therefore, must influence the perception of motor events. The hypothesis that dyspnoea is largely a sense of respiratory effort does not account for the findings that, at a comparable level of ventilation, dyspnoea is greater during hypercapnic hyperpnoea than exercise hyperpnoea 26. Changes in dyspnoea increase when the difference in alveolar carbon dioxide tension (P_CO2) between hypercapnia and exercise rises for similar levels of ventilation. A rise in arterial carbon dioxide tension (P_a,CO2), such as when holding one's breath, results in an urge to breathe and is easily recognised. Demediuk et al. 27 have shown that the urge to breathe at a constant level of ventilation increases with increasing P_CO2, whilst the sense of effort to breathe decreases. They provided evidence that qualitatively different sensations can result from voluntary (cortical) versus reflex (brainstem) drives to breathe, consistent with the possibility that corollary discharge from medullary respiratory centres gives rise to “air hunger”, whereas corollary discharge from the cortical motor centre gives rise to a sense of breathing effort 4. Dyspnoea augments at a constant level of ventilation when the breathing frequency is either voluntarily increased, or decreased with reciprocal changes in V_T from the spontaneous adopted level 28. These results are consistent with the possibility that breathing responses to change in chemical drive may be regulated, partially to minimise sensations of respiratory effort and discomfort 28, 29.

COPD and asthma

Physiological studies in patients with COPD have primarily investigated the intensity rather than quality of sensations. The effect of the physiological derangement of this condition increases both corollary discharge and central output to skeletal muscles, and probably reduces the peripheral instantaneous feedback from the lung and chest wall receptors. COPD patients, when exercised, report qualitative perceptions of “unsatisfied” or “unrewarded” inspiration, “shallow breathing” and “inspiratory difficulty”. These distinct sensations are associated with dynamic hyperinflation and its negative mechanical effects, i.e. threshold load and the uncoupling of the normal association between inspiratory effort and ventilatory output 19–21.

In these patients, hyperinflation during exercise probably contributes more to the mechanical problems than the increase in airflow resistance or decrease in dynamic pulmonary compliance 30. The important consequence of dynamic hyperinflation is the severe mechanical constraint on V_T expansion 19, 22.

In patients with asthma, symptoms following MCh inhalation were similar to those experienced during spontaneous asthma 17, 31. Of 28 patients with asthma, 50% chose the descriptions “my chest feels tight” or “my chest is constricted” to describe their dyspnoea, whereas none of the 22 patients with COPD and only 13% of the 16 patients with ILD selected these descriptors 5. These findings are in line with the clinical observation that chest tightness is the most probable manifestation of asthma.

Lougheed et al. 31 also showed that patients selected two descriptors: the first was associated with airway obstruction, and the second, “inspiratory difficulty”, was coincident with the association of increased airway obstruction with hyperinflation. For any given forced expiratory volume in one second (FEV₁) decrease, a progressive increase in airway narrowing was associated with a greater shifting in the Borg score of inspiratory difficulty. Killian et al. 6 stated that the many descriptors that characterise bronchial asthma indicate that different pathophysiological mechanisms are potentially in action, and suggested the possibility of distinguishing among them by utilising symptom discrimination. By using Thurstone's law of comparative judgment, they calculated the sensory distance between any two symptoms in discriminal dispersion units. The discrimination analysis showed symptoms (chest tightness and chest pain) that were easily discriminated, whereas other symptoms (breathlessness and air hunger) were not. Symptoms that can be reliably discriminated imply different pathophysiological mechanisms, whereas symptoms that cannot be reliably discriminated imply similar pathophysiological mechanisms. The study by Killian et al. 6 has also shown that dyspnoea is more intense with bronchoconstriction, baseline pulmonary impairment, weight and female sex; furthermore, dyspnoea is less intense with age, bronchial hyperresponsiveness, a low level of fear, coping and adaptation.

In induced asthma, Moy et al. 32 showed that the initial sensation of chest tightness reflects the breathing discomfort resulting from mild bronchoconstriction; with a more severe FEV₁ decrease and hyperinflation, the sensation of work or effort of breathing takes place, which may be due to the related inflammatory component of asthma and associated mechanical load on the ventilatory muscles 33. Therefore, there appears to be two distinct sensations of dyspnoea. The first sensation to be relieved with β₂-agonist treatment is chest tightness, which probably arises from stimulation of pulmonary receptors secondary to bronchospasm. The second, work/effort, is probably associated with both dynamic hyperinflation and more severe airway obstruction. Like patients with asthma, patients with cystic fibrosis select the cluster “tight” 5. As airway reactivity/bronchoconstriction is a common feature of these diseases, it is possible that the descriptor “my chest feels tight” originates from airway receptors and reflects airway tone. Due to the underlying mechanism, the score of chest tightness does not decrease with assisted ventilation compared with spontaneous breathing during MCh-induced bronchoconstriction; for the same reason, the chest tightness score is higher with bronchospasm and hyperinflation than with ventilatory-induced hyperinflation and positive end-expiratory pressure 17.

The language of dyspnoea is a useful supplement to overall ratings of dyspnoea intensity whilst monitoring the response to bronchodilator therapy in patients with acute asthma. Assessments of the intensity of dyspnoea alone may not accurately reflect the level of persistent airway obstruction. The global rating of dyspnoea, in conjunction with frequency-intensity rating of work/effort, may reflect the persistence of obstruction–inflammation of the airways more clearly than ratings of overall intensity of dyspnoea alone 34. Thus, attention to the language of dyspnoea would alert healthcare providers to significant remaining airway obstruction, despite improvements in, or resolution of overall dyspnoea when assessed by general rating of the intensity of breathing discomfort 34.

If it is acknowledged that asthma and COPD involve different pathophysiological derangement, it is also conceivable to accept the possibility of different descriptors for the two conditions. Harver et al. 35 provided preliminary evidence that chest tightness characterises asthma more than COPD. The reported sensitivity of tightness (i.e. the probability of diagnosing asthma in patients who have asthma) was 86% for asthma and 7% for COPD; the specificity (i.e. the probability of excluding asthma in patients who do not have asthma) was 69% and 64%, respectively. The data indicate that >86% of patients who report chest tightness have asthma, not COPD, and ∼69% of patients who do not report chest tightness do not have asthma. Another descriptor (“I feel I cannot get a deep breath”) has high specificity for COPD (72%), but a lower specificity for asthma (61%), and a low sensitivity for both conditions (37% and 50%, respectively).

Interstitial/restrictive lung disease

Harty et al. 23 and O'Donnell et al. 36 reported on the pattern of qualitative response selected with thoracic restriction in exercising normal subjects. Subjects frequently identified work/effort, unsatisfied inspiration, inspiratory difficulty, rapid and shallow as appropriate descriptors of their breathing, a set of qualitative responses similar to those reported by patients with restrictive lung disease (RLD) 1, 2, 5, 22. These sensations have their physiological basis partially in an impaired ability to increase lung volume and displace the thorax appropriately in the setting of an increased ventilatory drive. A slight variation in the patient's average V_T at rest provokes considerable dyspnoea, and this vulnerability to dyspnoea probably explains why the resting respiratory cycle is so tightly controlled in patients with RLD 29. Patients display a parabolic or U-shaped relationship between V_T and dyspnoea: a slight increase or decrease in V_T from the average resting value causes a marked increase in dyspnoea. The former is associated with greater respiratory work, whereas the latter is associated with increased dead space ventilation and hypercapnia 29. Lansing et al. 37 found that air hunger rating changes more deeply when P_a,CO2 is altered and minute ventilation (V′_E) is constant, whereas the work/effort rating changes more deeply when V′_E increases and P_a,CO2 is constant. The U-shaped curve relating difficulty of breathing to V′_E, with the V′_E at the centre of the spontaneous breathing level 28, 29, probably describes the effects of two different sensations: the left limb describes air hunger, and the right limb describes work/effort 37.

Neuromuscular disease

In patients with neuromuscular disease (NMD), a normal inspiratory motor output per unit change in P_CO2 results in a shallower breathing pattern 38. The consequent impairment of neuroventilatory coupling underlies the high scoring of dyspnoea in these patients (fig. 1⇓). In turn, the association of muscle weakness and elastic load in NMD is responsible for the modulation of a normal central respiratory output into a shallow pattern of breathing. Studies raise the possibility that NMD 38, COPD 20, 21, ILD 22 and airway involvement in multi-system disease 39 share common mechanisms underlying the discomfort associated with the act of breathing. A common underlying pathophysiological mechanism explains the similarity of clusters selected in different disorders 6.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1—

Schematic presentation of changes in inspiratory effort and volume. Increase in inspiratory effort was associated with an increase in dyspnoea. •: neuromuscular disease patients; ○: control subjects. Modified from 40.

Lanini et al. 40 showed that an increased inspiratory elastic load in stroke patients is translated into an increased inspiratory motor output (IMO). However, contrary to the initial hypothesis that in patients with abnormalities in respiratory mechanics an increase in IMO could translate into an increased perception of dyspnoea, the perception of dyspnoea was unexpectedly blunted in patients. This is probably because of the abnormality in the mechanisms of the process of integration of the afferent sensation. If the increased IMO does not transmit the corollary discharge to the sensory centre, an unchanged perception may result. Might this be due to functional abnormalities of the sensory cortex? In this regard, Peiffer et al. 41 performed a functional imaging study by positron emission tomography to identify brain region activation associated with an important component of respiratory discomfort during loaded breathing in healthy subjects. They found that highly loaded breathing was associated with neural activation of a distinct brain region identifying areas where regional blood flow was related to the mean amplitude of mouth pressure swings, and areas where neural activation was specifically associated with perceived intensity of respiratory discomfort that was not related to mouth pressure swings. Peiffer et al. 41 speculated that the main activation areas are part of a neural network involved in the process of two parallel integrations: the genesis and perception of respiratory discomfort, and modulation of the perceived intensity. In turn, the hypothesis that damage to the sensory cortex attenuates the effect of the corollary discharge, which could influence a patient's ability to perceive dyspnoea, may not be excluded 40.

Congestive heart disease

Patients with chronic heart failure (CHF) complain of exercise limitation. When requested to describe their dyspnoea, they select the cluster “suffocating at rest”, rapid breathing, air hunger 1, a “need to sigh” 2 or work/effort during exercise 5. The explanation of the underlying pathophysiology is not easy because of the conflicting data reporting on whether respiratory function contributes to exercise limitation in CHF patients. Clark et al. 42 have shown that these patients may stop exercising because of intolerable exertional dyspnoea, leg fatigue or both, at a point where there is apparent cardiopulmonary reserve.

O'Donnell et al. 43 showed that inspiratory pressure support decreases leg effort, probably by reducing the left ventricular afterload, increasing peripheral blood flow and improving local acid-base equilibrium, which reduces muscular afferents associated with the perception of “effort”. Nonetheless, the observation of no evident effect on dyspnoea during the constant load exercise test suggests that factors other than mechanical loading contribute predominantly to dyspnoea.

Hamilton et al. 44, and more recently Killian 45 (in a larger series of 16.000 patients), have determined the mechanisms of exercise intolerance and the limiting complaints (dyspnoea or leg fatigue) in patients with angina, pulmonary impairment, ischaemic heart disease or cardiopulmonary disease. Their studies reveal a simple picture. When patients were subdivided according to exercise tolerance, the intensity of both dyspnoea and leg effort increased as exercise tolerance decreased for all disease types. The proportion of patients limited by dyspnoea, leg effort, or a combination of both was similar for all disease types. Only the angina group selected “chest pain”. Verbal descriptors may help differentiate between patients with CHF and deconditioned patients who describe “heavy breathing” 46.