Volumetric capnography <i>versus</i> spirometry for the evaluation of pulmonary function in cystic fibrosis and allergic asthma

Almeida-Junior, Armando; Marson, Fernando Augusto Lima; Almeida, Celize Cruz Bresciani; Ribeiro, Maria Ângela Gonçalves Oliveira; Paschoal, Ilma Aparecida; Moreira, Marcos Mello; Ribeiro, José Dirceu

doi:10.1016/j.jped.2018.10.008

Abstract

Objective:

To compare the values of the markers for volumetric capnography and spirometry and their ability to classify children and adolescents with asthma, cystic fibrosis (CF), and healthy controls.

Methods:

This was a cross-sectional study that included 103 patients with controlled persistent allergic asthma, 53 with CF and a healthy control group with 40 volunteers (aged 6 to 15 years), of both sexes. The individuals underwent volumetric capnography and spirometry.

Results:

Phase III slope (SIII), SIII standardized by exhaled tidal volume (SIII/TV) and capnographic index (SIII/SII) × 100 (KPIv) were different among the three groups assessed, with highest values for CF. The relation between the forced expiratory volume in one second and the forced vital capacity (FEV₁/FVC) was the only spirometric marker that presented difference on the three groups. On individuals with normal spirometry, KPIv and FEV₁/FVC were different among the three groups. The ROC curve identified the individuals with asthma or CF from the control group, both through volumetric capnography (better to identify CF in relation to the control using KPIv) and through spirometry (better to identify asthma in relation to the control). KPIv was the best parameter to distinguish asthma from CF, even in individuals with normal spirometry.

Conclusion:

Volumetric capnography and spirometry identified different alterations in lung function on asthma, CF, and healthy controls, allowing the three groups to be distinguished.

KEYWORDS
Asthma; Cystic fibrosis; Pulmonary function; Spirometry; Volumetric capnography

Resumo

Objetivo

Comparar os valores dos marcadores para capnografia volumétrica e espirometria e sua capacidade de classificar crianças e adolescentes com asma, fibrose cística (FC) e controles saudáveis.

Métodos

Foi realizado um estudo transversal que incluiu 103 pacientes com asma alérgica persistente controlada, 53 com FC e um grupo controle saudável com 40 voluntários (6 a 15 anos), de ambos os sexos. Os indivíduos foram submetidos a capnografia volumétrica e espirometria.

Resultados

O slope da fase III (SIII), SIII padronizada pelo volume tidal exalado (SIII/VT) e o índice capnográfico (SIII/SII) × 100 (KPIv) foram diferentes entre os três grupos avaliados, com maiores valores para o grupo FC. A relação entre o volume expiratório forçado no primeiro segundo e a capacidade vital forçada (VEF₁/CVF) foi o único marcador de espirometria com diferenças nos três grupos. Nos indivíduos com espirometria normal, o KPIv e VEF_1/CVF foram diferentes entre os três grupos. A curva ROC diferenciou os indivíduos com asma ou FC daqueles do grupo controle, ambos através da capnografia volumétrica (melhor para identificar a FC em relação aos controles pelo KPIv) e por meio da espirometria (melhor para identificar a asma em relação aos controles). O KPIv foi o melhor parâmetro para distinguir a asma da FC, mesmo em indivíduos com espirometria normal.

Conclusão

A capnografia volumétrica e a espirometria identificaram diferentes alterações de função pulmonar na asma, na FC e nos controles saudáveis, permitiram que os três grupos fossem diferenciados.

PALAVRAS-CHAVE
Asma; Fibrose cística; Função pulmonar; Espirometria; Capnografia volumétrica

Introduction

Asthma is among the most common chronic disease in children and adolescents; in turn, cystic fibrosis (CF) is little prevalent.¹1 Ribeiro JD, Fischer GB. Chronic obstructive pulmonary diseases in children. J Pediatr (Rio J). 2015;91:S11-25. Both chronic lung diseases (CF and asthma) present with airway obstruction, but each has a different pathophysiology. Several instruments have been studied and proposed to assess the anatomical and functional damage caused by both diseases. Volumetric capnography (VCap) allows the graphical analysis of the concentration pattern of carbon dioxide (CO₂) in the exhaled air volume, representing the anatomical source of CO₂. Three phases can be identified during VCap,²2 Fowler WS. Lung function studies; the respiratory dead space. Am J Physiol. 1948;154:405-16.^,³3 Fletcher R, Jonson B, Cumming G, Brew J. The concept of dead space with special reference to the single breath test for carbon dioxide. Br J Anaesth. 1981;53:77-88. including the phase III slope (SIII), which is directly correlated with the degree of variation on the ventilation/perfusion in pulmonary injury model and varies in a high number of diseases.⁴4 Tusman G, Suarez-Sipmann F, Bohm SH, Borges JB, Hedenstierna G. Capnography reflects ventilation/perfusion distribution in a model of acute lung injury. Acta Anaesthesiol Scand. 2011;55:597-606.

5 Moreira MM, Terzi RG, Paschoal IA, Martins LC, Oliveira EP, Falcao AL. Thrombolysis in massive pulmonary embolism based on the volumetric capnography. Arq Bras Cardiol. 2010;95:e97-9.

6 Veronez L, Moreira MM, Soares ST, Pereira MC, Ribeiro MA, Ribeiro JD, et al. Volumetric capnography for the evaluation of pulmonary disease in adult patients with cystic fibrosis and non cystic fibrosis bronchiectasis. Lung. 2010;188:263-8.^-⁷7 Moreira MM, Terzi RG, Carvalho CH, de Oliveira Neto AF, Pereira MC, Paschoal IA. Alveolar dead space and capnographic variables before and after thrombolysis in patients with acute pulmonary embolism. Vasc Health Risk Manage. 2009;5:9-12. For newborns, SIII can possibly identify preterm infants with bronchopulmonary dysplasia from preterm infants with no pulmonary disease.⁸8 Fouzas S, Häcki C, Latzin P, Proietti E, Schulzke S, Frey U, et al. Volumetric capnography in infants with bronchopulmonary dysplasia. J Pediatr (Rio J). 2014;164:283-8. The angle between the slopes in phases II and III is known as capnographic index (KPIv) and can be used as a screening test for the severity of pulmonary disease in CF.⁹9 Fuchs SI, Junge S, Ellemunter H, Ballmann M, Gappa M. Calculation of the capnographic index based on expiratory molar mass-volume-curves a suitable tool to screen for cystic fibrosis lung disease. J Cyst Fibros. 2013;12:277-83. When compared with other tests of pulmonary function evaluation, VCap has the advantage of being portable, non-invasive, not using expensive gases, and being performed with spontaneous breathing.¹⁰10 Almeida CC, Almeida-Júnior AA, Ribeiro MA, Nolasco-Silva MT, Ribeiro JD. Volumetric capnography to detect ventilation in homogeneity in children and adolescents with controlled persistent asthma. J Pediatr (Rio J). 2011;87:163-8.

11 Parazzi PL, Marson FA, Ribeiro MA, Schivinski CI, Ribeiro JD. Use of volumetric capnography in submaximal exercise test: what did we learn?. J Genet Syndr Gene Ther. 2016;7:289.^-¹²12 Parazzi PL, Marson FA, Ribeiro JD, Ribeiro MA, Schivinski CI. Use of phase III slope of volumetric capnography in outpatient clinical practice: a descriptive analysis. Curr Respir Med Rev. 2017;13:152-8.

Also, the authors had observed that the SIII standardized by the exhaled tidal volume (SIII/TV) is higher in children with asthma, and may reflect the in homogeneity of ventilation, suggesting chronic structural respiratory diseases. After the methacholine challenge test, SIII increased, and subsequently decreased after inhalation therapy with bronchodilator agents. This fact suggests the asynchronism on the emptying of the alveolar units due to the constrictor action of methacholine on the peripheral airways.¹⁰10 Almeida CC, Almeida-Júnior AA, Ribeiro MA, Nolasco-Silva MT, Ribeiro JD. Volumetric capnography to detect ventilation in homogeneity in children and adolescents with controlled persistent asthma. J Pediatr (Rio J). 2011;87:163-8. An increase of the SIII value was observed on people with CF when compared with healthy children and adolescents. SIII values were higher in patients with normal spirometry, suggesting that VCap can identify patients with alterations in ventilation homogeneity very early.¹³13 Ribeiro MA, Silva MT, Ribeiro JD, Moreira MM, Almeida CC, Almeida-Junior AA, et al. Volumetric capnography as a tool to detect early peripheric lung obstruction in cystic fibrosis patients. J Pediatr (Rio J). 2012;88:509-17.

In hypothesis, the authors believe the VCap can pick up early pulmonary function abnormalities in the context of normal spirometry. Furthermore, while asthma is primarily an airway disease that can be described by spirometric abnormalities, CF is a mixed parenchymal/small airway disease that would be better described by VCap and in SIII of the capnogram. Thus, the objective of this study was to compare the markers for VCap and spirometry among children and adolescents with asthma, CF, and healthy controls. Moreover, the authors assessed the ability of the markers to identify to which group each individual belonged.

Methods

This was a cross-sectional, analytical, observational, and non-randomized study, conducted for three years at the Pulmonary Function Laboratory (LAFIP) of the University of Campinas to complete the recruitment. The project was approved by the Research Ethics Committee of the Institution (No. 419/2005 and No. 430/2008). The guardians of the children signed an informed consent form.

The study included three groups of individuals: (i) 103 with controlled persistent allergic asthma (AAG); (ii) 53 with CF (CFG) - outside the period of pulmonary exacerbations; and (iii) 40 volunteers as healthy controls (HCG). Patients were aged from six to 15 years, of both sexes. They were followed-up at the Pediatric Pulmonology Outpatient Clinic from University Hospital of the institution and were recruited during routine visits. All the patients followed-up at the service were invited to participate in the study and only those who accepted to participate were included.

The diagnosis and classification of asthma followed the criteria of the Global Initiative for Asthma (GINA). Patients with asthma presented a dosage of serum immunoglobulin E greater than 180 IU/mL on at least one blood sample, peripheral blood eosinophils >4%, and positive response to at least one tested antigen on skin tests of immediate hypersensitivity. The inclusion criteria for patients with asthma were those who used inhaled corticosteroid (budesonide) as dry powder at a dosage of 400-800 mcg/day, and formoterol 12 mcg twice/day, for at least 30 days. No patient had history of asthma attack requiring hospitalization in intensive care unit in the previous year, exacerbation or worsening of symptoms with need for increased use of inhaled bronchodilators or systemic corticosteroids for four weeks before the tests were performed.

The CF was diagnosed using the sweat test with stimulation of sweating through pilocarpine iontophoresis (at least two doses of chloride concentration greater than 60 mEq/L) and/or identification of two cystic fibrosis transmembrane conductance regulator (CFTR) mutations recognized as pathogenic mutations.

The HCG was composed of healthy volunteers, with no history of active or passive smoking, without prior or current respiratory disease, who used no medication and had no known comorbidities. The individuals included presented no great difficulties to perform spirometry and VCap.

The clinical characteristics of the participants were documented by the medical staff during the visits to perform the spirometry and VCap.

Volumetric capnography

To perform the VCap, the respiratory profile monitor CO₂SMO Plus® model DX-8100 (Novametrix, Wallingford, USA) was used; the software Analysis Plus (Oasis Analysis Plus®, MS, USA) was used to register the measurements and curves of the VCap. Participants were asked to sit with their back to the monitor, to use a nasal clip, and to breath through the mouthpiece. VCap markers were recorded for five minutes after observing the normalization of the respiratory pattern, and an offline sequence of the respiratory cycles of patients was selected after the collection, excluding the cycles of the first minute, considering it as a period of adaptation of the individual. After that procedure, the respiratory cycles that showed irregular patterns of the VCap curve, such as the absence of the plateau due to air leak or depression of the plateau due to cough, were excluded. The cycles in which the TV variation was greater or less than 25% of the average and in which the exhaled CO₂ was greater or less than 5% of the average were also excluded.¹⁰10 Almeida CC, Almeida-Júnior AA, Ribeiro MA, Nolasco-Silva MT, Ribeiro JD. Volumetric capnography to detect ventilation in homogeneity in children and adolescents with controlled persistent asthma. J Pediatr (Rio J). 2011;87:163-8.^,¹³13 Ribeiro MA, Silva MT, Ribeiro JD, Moreira MM, Almeida CC, Almeida-Junior AA, et al. Volumetric capnography as a tool to detect early peripheric lung obstruction in cystic fibrosis patients. J Pediatr (Rio J). 2012;88:509-17.^,¹⁴14 Romero PV, Rodrigues B, de Oliveira D, Blanch L, Manresa F. Volumetric capnography and chronic obstructive pulmonary disease staging. Int J Chron Obstruct Pulmon Dis. 2007;2:381-91.

The average of the markers of the remaining cycles were calculated and considered as the final result. Three phases can be identified during VCap: phase I corresponds to the anatomic dead space; phase II, to a rapid increase of CO₂; phase III, to the formation of the plateau of exhaled CO₂ corresponding to the alveolar air volume.²2 Fowler WS. Lung function studies; the respiratory dead space. Am J Physiol. 1948;154:405-16.^,³3 Fletcher R, Jonson B, Cumming G, Brew J. The concept of dead space with special reference to the single breath test for carbon dioxide. Br J Anaesth. 1981;53:77-88. The markers analyzed were: SII and SIII. The capnographic index [(SIII/SII) × 100] (KPIv) was also used.⁸8 Fouzas S, Häcki C, Latzin P, Proietti E, Schulzke S, Frey U, et al. Volumetric capnography in infants with bronchopulmonary dysplasia. J Pediatr (Rio J). 2014;164:283-8.^,⁹9 Fuchs SI, Junge S, Ellemunter H, Ballmann M, Gappa M. Calculation of the capnographic index based on expiratory molar mass-volume-curves a suitable tool to screen for cystic fibrosis lung disease. J Cyst Fibros. 2013;12:277-83.^,¹⁵15 Stromberg NO, Gustafsson PM. Ventilation in homogeneity assessed by nitrogen washout and ventilation-perfusion mismatch by capnography in stable and induced airway obstruction. Pediatr Pulmonol. 2000;29:94-102. The normalization of SII and SIII by TV (SII/TV and SIII/TV) was performed to compensate for variations on the size of the individuals.

Spirometry

For the evaluation of spirometry the spirometer CPFS/D and the BREEZE PF® version 3.8 B software (MedGraphics, MN, USA) were used. The screening was performed according to the recommendations of the European Respiratory Society and American Thoracic Society.¹⁶16 Miller MR, Hankinson J, Brusasco V, Burgos F, Casaburi R, Coates A, et al. Standardisation of spirometry. Eur Respir J. 2005;26:319-38. Patients were instructed not to use bronchodilators of short or long duration for 12 h before the exam. The spirometry markers were adjusted to the Z-score using the GLI2012 software provided by the Global Lung initiative (GLI) of the European Respiratory Society.¹⁷17 Quanjer PH, Stanojevic S, Cole TJ, Baur X, Hall GL, Culver BH, et al. Multi-ethnic reference values for spirometry for 3-95 yr age range: the global lung function 2012 equations. Eur Respir J. 2012;40:1324-43. The following markers were used in this study: forced vital capacity (FVC), forced expiratory volume in one second of the FVC (FEV₁), index of obstruction (FEV₁/FVC), and forced expiratory flow between 25% and 75% of the FVC (FEF_25-75%), expressed as Z-score and predicted percentage.

Statistical analysis

Comparisons between independent markers without normal distribution were performed using the Mann-Whitney test.

The receiver operating characteristic (ROC) curve and the area under the ROC curve (AUC) were calculated to assess the potential of the spirometry and VCap markers to identify patients with asthma from healthy controls, patients with CF from healthy controls, and between patients with CF from those with asthma. VCap markers that were different in the three groups in the association study were used for the analysis of the ROC curve.

The predicted percentage was used due to its extensive use in clinical practice.¹⁸18 O'Neill K, Tunney MM, Johnston E, Rowan S, Downey DG, Rendall J, et al. Lung Clearance index in adults and children with cystic fibrosis. Chest. 2016;150:1323-32. Values below 80% of the predicted for spirometry markers were considered to be below the lower limit of normal (LLN). The Z-scores of the VCap markers for the HCG were calculated. The LLN and the upper limit of normal (ULN) for the VCap markers were considered as <−2 and >+2 of the HCG Z-score. A subgroup of individuals from the three groups was considered to have "normal" spirometry, using as inclusion criteria the results of FVC, FEV₁, and FEV₁/FVC greater than the LLN (at least 80% of the predicted to all these markers from spirometry).

To compare the groups and analyze the ROC curve, SPSS (SPSS Inc., Statistical Package for Social Sciences, version 16.0, Chicago, IL, USA) was used. The value of alpha adopted was of 0.05.

The graphs for median and confidence interval were performed using MedCalc 16.4.3 (MedCalc Software bvba - Ostend, Belgium; https://www.medcalc.org, 2016).

Results

The descriptive analysis of the anthropometric variables and data obtained from the VCap and spirometry between AAG, CFG and HCG are presented in Table 1 and Fig. 1. CF patients had smaller height and weight when compared with healthy controls and patients with asthma. The SIII, SIII/TV, and KPIv were higher in the groups of respiratory diseases in relation to the control group, being worse in the CFG. Only the FEV₁/FVC presented the same degree of evidence (p-value <0.05), with the lowest values on the AAG. With the exception of SII, the other markers of VCap and all markers of spirometry separated the HCG from the AAG and CFG (p-value <0.05).

Figure 1
Association of the parameters measured in volumetric capnography between healthy control individuals (n = 40) and patients with asthma (n = 103), and cystic fibrosis (n = 53). Data presented by the median (red dot) and 95% confidence interval (green intersection). (A) SIII (healthy control) 12.08; (asthma) 17.55; (cystic fibrosis - CFG) 27.86. (B) SIII/TV: SIII: (healthy control) 0.03; (asthma) 0.05; (CFG) 0.08. (C). KPIv: (healthy control) 2.53; (asthma) 3.41; (CFG) 4.96. Data are presented as median. Alpha = 0.05. All data presented p-value with positive association (p-value < 0.05). The SII and SIII are presented in mmHg, millimeters of mercury. Statistical analysis was performed using the Mann-Whitney test, and the authors compared two groups each time. mmHg, millimeters of mercury; L, liters; TV, exhaled tidal volume; SII, phase II slope; SIII, phase III slope; KPIv, ratio between the SII and SIII multiplied by 100.

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Table 1
Association of anthropometric variables and data obtained through volumetric capnography and spirometry between the healthy control group (HCG) and patients with asthma (AAG) or cystic fibrosis (CFG).

The analysis of individuals with normal spirometry evidenced that, with the exception of FVC, all markers were different between the HCG and patients (AAG and CFG). However, only the values of KPIv (higher on the CFG) and FEV₁/FVC (lower on the AAG) were different between the AAG and CFG.

The AUC for the VCap and spirometry between the HCG and patients (AAG and CFG), as well as between the AAG and CFG, are presented in Table 1 and Fig. 2. On the discrimination of the HCG from the AAG, the markers were different (p-value <0.05); however, only FEV₁ and FEV₁/FVC presented AUC values greater than 0.800.

Figure 2
Area under the curve for volumetric capnography and spirometry between the control group (HCG, n = 40), the group of patients with asthma (AAG, n = 103), and the group of patients with cystic fibrosis (CFG, n = 53). TV, exhaled tidal volume; SIII, phase III slope; KPIv, ratio between the SII and SIII multiplied by 100; FEV₁, forced expiratory volume in one second of the FVC; FVC, forced vital capacity; FEF_25-75%, forced expiratory flow between 25% and 75% of the FVC.

On the discrimination of the HCG from the CFG, the markers presented differences between the groups (p-value <0.05), with the highest AUC value for FEV₁/FVC and VCap markers; the highest AUC value was observed for KPIv (0.900). Similarly, the VCap and FEV₁/FVC markers differentiated the AAG and CFG, and KPIv presented the highest AUC value (0.763).

When the individuals with normal spirometry were evaluated, the VCap presented AUC values capable of discriminating the HCG from the AAG (SIII = 0.768, p-value <0.001; SIII/TV = 0.730, p-value <0.001; KPIv = 0.686, p-value = 0.002); as well as the HCG from the CFG (KPIv = 0.866, p-value <0.001; SIII = 0.822, p-value <0.001; SIII/TV = 0.742, p-value = 0.001). The AUCs that differentiated the HCG from the AAG in spirometry were: FEV₁/FVC (predicted %) = 0.814 (p-value < 0.001) and FEV₁ (predicted %) = 0.726 (p-value < 0.001). Between the HCG and CFG, the FEV₁ and FEV₁/FVC (predicted %) values were different (p-value < 0.05; AUC = 0.712 and 0.702, respectively).

The discrimination of the AAG from the CFG in individuals with normal spirometry was done by KPIv (AUC = 0.702, p-value = 0.003) and FEV₁/FVC (%) (AUC = 0.683, p-value = 0.006).

Fig. 3 presents the relation between spirometry and KPIv markers on the three groups studied.

Figure 3
Association of KPIv on volumetric capnography with spirometry markers between healthy control individuals (n = 40) and patients with asthma (n = 103) or cystic fibrosis (n = 53), considering the distinction between spirometry markers above and below the LLN (80%) and KPIv above and below the ULN (KPIv = 4.23). (A) KPIv versus FEV₁ (predicted %). (B) KPIv versus FVC (predicted %). (C) KPIv versus FEV₁/FVC (predicted %). (D) KPIv versus FEF_25-75% (predicted %). Each graph is divided into four quadrants corresponding to the following conditions: Altered KPIv and spirometry marker; altered KPIv and normal spirometry marker; normal KPIv and altered spirometry marker; normal KPIv and spirometry marker. KPIv, ratio between the SII and SIII multiplied by 100; FEV₁, forced expiratory volume in one second of the FVC; FVC, forced vital capacity; FEF_25-75%, forced expiratory flow between 25% and 75% of the FVC; LLN, lower limit of normal; ULN, upper limit of normal. Black circle, healthy control individuals; green circle, patients with asthma; red triangle, patients with cystic fibrosis.

Discussion

To the best of the authors' knowledge, no other studies assessed the ability of the VCap markers to discriminate individuals with asthma from individuals with CF and healthy controls, in comparison to spirometry markers. Moreover, an unprecedented and robust finding was that SIII, SIII/TV and KPIv were different among the three groups assessed, with highest values for CF. The FEV₁/FVC was the only marker of spirometry with difference on the three groups. In addition, on individuals with normal spirometry, KPIv, and FEV₁/FVC were different among the three groups. Moreover, the ROC curve identified the individuals with asthma or CF from the control group, both through VCap (better to identify CF in relation to the control using KPIv) and spirometry (better to identify asthma in relation to the control). KPIv was the best parameter to distinguish asthma from CF, even in individuals with normal spirometry.

The search for methods to evaluate pulmonary function in children and adolescents with chronic lung diseases with airway obstruction is a constant struggle in the scientific community. Spirometry is the most used instrument for randomized clinical trials as primary outcome.¹⁹19 Swystun V, Green FH, Dennis JH, Rampakakis E, Lalli G, Fadayomi M, et al. A phase IIa proof-of-concept, placebo-controlled, randomized, double-blind, crossover, single-dose clinical trial of a new class of bronchodilator for acute asthma. Trials. 2018;19:321.

20 Taylor-Cousar JL, Munck A, McKone EF, van der Ent CK, Moeller A, Simard C, et al. Tezacaftor-ivacaftor in patients with cystic fibrosis homozygous for Phe508del. N Engl J Med. 2017;377:2013-23.

21 Rowe SM, Daines C, Ringshausen FC, Kerem E, Wilson J, Tullis E, et al. Tezacaftor-ivacaftor in residual-function heterozygotes with cystic fibrosis. N Engl J Med. 2017;377:2024-35.^-²²22 Donaldson SH, Pilewski JM, Griese M, Cooke J, Viswanathan L, Tullis E, et al. Tezacaftor/ivacaftor in subjects with cystic fibrosis and F508del/F508del-CFTR or F508del/G551D-CFTR. Am J Respir Crit Care Med. 2018;197:214-24. However, the use of spirometry will always be criticized, despite its importance, mainly due to the large intrapersonal variability and the lack of equations for distinct populations. Therefore, comparing spirometry to other methods is promising.

Children present numerous chronic lung diseases with airway obstruction, and each of them presents greater or lesser degrees of inflammation and bronchial reactivity on upper and/or lower airways.¹1 Ribeiro JD, Fischer GB. Chronic obstructive pulmonary diseases in children. J Pediatr (Rio J). 2015;91:S11-25. Each assessment instrument will most likely have greater or lesser effectiveness depending on the chronic lung disease, as shown in Fig. 3 for VCap and spirometry. The search to characterize the usefulness of these methods focuses on finding anatomical (computed tomography of the thorax) and functional (spirometry, impulse oscillometry system, lung clereance index [LCI], and plestimography, among others) alterations. Among the diseases included in the present study, asthma differs from CF considering the initial predominance of obstruction, maintenance, and progression of the fixed airway obstruction. Asthma affects the larger airways; if left untreated, progresses to the smaller airways.²³23 Usmani OS. Small airways dysfunction in asthma: evaluation and management to improve asthma control. Allergy Asthma Immunol Res. 2014;6:376-88. In turn, the opposite happens in CF: the disease starts on the small airways and progresses toward the large airways.²⁴24 Tiddens HA, Donaldson SH, Rosenfeld M, Paré PD. Cystic fibrosis lung disease starts in the small airways: can we treat it more effectively?. Pediatr Pulmonol. 2010;45:107-17. These findings are illustrated in Fig. 3.

VCap slopes assess the volumetric part of the airways, where the movement of gases occurs by diffusion. Conversely, spirometry better evaluates flow alterations on the conducting airways, as the movement of gases in this region is more intense due to convection. Therefore, it was expected that there were differences between the results of these instruments on the evaluation of the numerous chronic lung diseases with airway obstruction in children, resulting from compromises in proximal or distal airways.

Gustafsson et al. compared asthma and CF using LCI and spirometry; their results, as well as the present results, suggest that the airway alterations in CF affect the lung periphery more extensively than in asthma.²⁵25 Gustafsson PM. Peripheral airway involvement in CF and asthma compared by inert gas washout. Pediatr Pulmonol. 2007;42:168-76. Moreover, Fuchs et al. presented the association between KPIv from VCap and LCI.⁹9 Fuchs SI, Junge S, Ellemunter H, Ballmann M, Gappa M. Calculation of the capnographic index based on expiratory molar mass-volume-curves a suitable tool to screen for cystic fibrosis lung disease. J Cyst Fibros. 2013;12:277-83. In the present data, differences were observed between spirometry and VCap in the HCG, AAG, and CFG, as well as the presence of concurrently altered spirometry and KPIv in the CFG. Additionally, normal spirometry occurred in the CFG and AAG (as well as in the HCG group). Numerous patients with CF and normal spirometry presented altered KPIv, suggesting that the alterations assessed by VCap can occur earlier than in spirometry; this fact was previously documented regarding other VCap markers and LCI.¹³13 Ribeiro MA, Silva MT, Ribeiro JD, Moreira MM, Almeida CC, Almeida-Junior AA, et al. Volumetric capnography as a tool to detect early peripheric lung obstruction in cystic fibrosis patients. J Pediatr (Rio J). 2012;88:509-17.^,²⁶26 Gustafsson PM, Aurora P, Lindblad A. Evaluation of ventilation maldistribution as an early indicator of lung disease in children with cystic fibrosis. Eur Respir J. 2003;22:972-9. A similar behavior was observed between the LCI and FEV₁ in CF.²⁷27 Aurora P, Gustafsson P, Bush A, Lindblad A, Oliver C, Wallis CE, et al. Multiple breath inert gas washout as a measure of ventilation distribution in children with cystic fibrosis. Thorax. 2004;59:1068-73. In turn, patients with asthma may present altered spirometry with normal KPIv, suggesting that flow alterations are more frequent and affect the proximal airways. Patients with asthma who present normal spirometry and altered KPIv would be harder to explain. These individuals could present less known phenotypes that should be assessed with functional and inflammatory biomarkers to characterize the type of asthma.

To highlight the importance of VCap on the assessment of pulmonary diseases versus spirometry, the authors used the ROC curve to discriminate between the different groups. In the present data, VCap was proven to be a useful instrument to differentiate patients with CF from healthy controls (on both adults and children)⁶6 Veronez L, Moreira MM, Soares ST, Pereira MC, Ribeiro MA, Ribeiro JD, et al. Volumetric capnography for the evaluation of pulmonary disease in adult patients with cystic fibrosis and non cystic fibrosis bronchiectasis. Lung. 2010;188:263-8.^,¹³13 Ribeiro MA, Silva MT, Ribeiro JD, Moreira MM, Almeida CC, Almeida-Junior AA, et al. Volumetric capnography as a tool to detect early peripheric lung obstruction in cystic fibrosis patients. J Pediatr (Rio J). 2012;88:509-17. and to differentiate children, adolescents, and adults with asthma from their healthy peers.¹⁰10 Almeida CC, Almeida-Júnior AA, Ribeiro MA, Nolasco-Silva MT, Ribeiro JD. Volumetric capnography to detect ventilation in homogeneity in children and adolescents with controlled persistent asthma. J Pediatr (Rio J). 2011;87:163-8.^,²⁸28 Subbotin SV, Ponomaryova IB, Byalovskiy YY, Abrosimov VN. Volumetric capnography to assess functional respiratory disturbances in patients with bronchial asthma. CTM. 2017;9:93-101.

The spirometry markers (FEV₁ and FEV₁/FVC) were better than the VCap to differentiate the AAG and HCG on the ROC curve. Conversely, VCap markers presented a greater AUC to distinguish CFG and HCG. O'Neal et al. found a higher AUC with LCI than with spirometry, when differentiating CF and healthy controls.¹⁸18 O'Neill K, Tunney MM, Johnston E, Rowan S, Downey DG, Rendall J, et al. Lung Clearance index in adults and children with cystic fibrosis. Chest. 2016;150:1323-32.

Spirometry and VCap were effective to differentiate healthy individuals from patients with pulmonary disease. Regarding the difference between AAG and CFG, only KPIv and FEV₁/FVC were significant, and KPIv was higher (AUC > 0.700).

When evaluating the individuals with normal spirometry, VCap markers indicated a greater compromise of the ventilation homogeneity on CF and AAG compared to the control group. However, VCap was better than spirometry to differentiate the HCG from the CFG. In this situation, VCap was also better than spirometry to discriminate between the CFG and AAG, considering an AUC ≥ 0.700.

The present study had some limitations: (i) it did not have a prospective design and the VCap measures were not repeated; (ii) VCap is limited to assess clinimetric properties and this does not change the perception of the potential of VCap as clinical and scientific instrument in the context of pulmonary diseases in pediatrics; (iii) the sample size was chosen by convenience; and (iv) only one center was enrolled.

In conclusion, the present study showed that the SIII, SIII/TV, and KPIv obtained from VCap, and the FEV₁ and FEV₁/FVC from spirometry, were good markers to discriminate the HCG from AAG and CFG. The authors believe that for each chronic lung diseases with airway obstruction, different markers of pulmonary function deterioration will be more useful. Finally, VCap can describe earlier and more accurately the pathophysiology of CF than spirometry.

☆
Please cite this article as: Almeida-Junior A, Marson FA, Almeida CC, Ribeiro MÂ, Paschoal IA, Moreira MM, et al. Volumetric capnography versus spirometry for the evaluation of pulmonary function in cystic fibrosis and allergic asthma. J Pediatr (Rio J). 2020;96:255-63.
☆☆
The study was performed at the Laboratório de Fisiologia Pulmonar (Lafip), Centro de Investigação em Pediatria (Ciped), Faculdade de Ciências Médicas, Universidade Estadual de Campinas, Campinas, SP, Brazil.

Acknowledgements

FALM: Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) for research grants and scholarships #2011/12939-4, #2011/18845-1, #2015/12183-8 and #2015/12858-5; Fundo de Apoio à Pesquisa, ao Ensino e à Extensão da Universidade Estadual de Campinas for research support #0648/2015; JDR: FAPESP for research assistance 2011/18845-1 and #2015/12183-8.

To Luciana Montes Rezende, Luciana Cardoso Bonadia, Maria de Fátima Corrêa Pimenta Servidoni, Carlos Emílio Levy, Adressa Oliveira Peixoto, Adyléia Aparecida Contrera Dalbo Toro, Renan Marrichi Mauch, Roberto José Negrão Nogueira, Eulália Sakano, Antônio Fernando Ribeiro, Carla Cristina de Souza Gomez, Elizete Aparecida Lomazi, Paloma Lopes Francisco Parazzi, Larissa Lazzarini Furlan, Emília da Silva Gonçalves, Aline Cristina Gonçalves, Milena Baptistella Grotta Silva, and Alethea Guimarães Faria, who contribute to studies carried out on cystic fibrosis in our reference center.

References

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¹⁰
Almeida CC, Almeida-Júnior AA, Ribeiro MA, Nolasco-Silva MT, Ribeiro JD. Volumetric capnography to detect ventilation in homogeneity in children and adolescents with controlled persistent asthma. J Pediatr (Rio J). 2011;87:163-8.
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Parazzi PL, Marson FA, Ribeiro MA, Schivinski CI, Ribeiro JD. Use of volumetric capnography in submaximal exercise test: what did we learn?. J Genet Syndr Gene Ther. 2016;7:289.
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¹³
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Romero PV, Rodrigues B, de Oliveira D, Blanch L, Manresa F. Volumetric capnography and chronic obstructive pulmonary disease staging. Int J Chron Obstruct Pulmon Dis. 2007;2:381-91.
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Donaldson SH, Pilewski JM, Griese M, Cooke J, Viswanathan L, Tullis E, et al. Tezacaftor/ivacaftor in subjects with cystic fibrosis and F508del/F508del-CFTR or F508del/G551D-CFTR. Am J Respir Crit Care Med. 2018;197:214-24.
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²⁶
Gustafsson PM, Aurora P, Lindblad A. Evaluation of ventilation maldistribution as an early indicator of lung disease in children with cystic fibrosis. Eur Respir J. 2003;22:972-9.
²⁷
Aurora P, Gustafsson P, Bush A, Lindblad A, Oliver C, Wallis CE, et al. Multiple breath inert gas washout as a measure of ventilation distribution in children with cystic fibrosis. Thorax. 2004;59:1068-73.
²⁸
Subbotin SV, Ponomaryova IB, Byalovskiy YY, Abrosimov VN. Volumetric capnography to assess functional respiratory disturbances in patients with bronchial asthma. CTM. 2017;9:93-101.

Publication Dates

Publication in this collection
11 May 2020
Date of issue
Mar-Apr 2020

History

Received
15 Aug 2018
Accepted
14 Oct 2018
Published
7 Dec 2018

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ☆
Please cite this article as: Almeida-Junior A, Marson FA, Almeida CC, Ribeiro MÂ, Paschoal IA, Moreira MM, et al. Volumetric capnography versus spirometry for the evaluation of pulmonary function in cystic fibrosis and allergic asthma. J Pediatr (Rio J). 2020;96:255-63.

[2] ☆☆
The study was performed at the Laboratório de Fisiologia Pulmonar (Lafip), Centro de Investigação em Pediatria (Ciped), Faculdade de Ciências Médicas, Universidade Estadual de Campinas, Campinas, SP, Brazil.

Markers	HCG (n = 40)	AAG (n = 103)	CFG (n = 53)	HCG versus AAG (p-value)	HCG versus CFG (p-value)	AAG versus CFG (p-value)
Age (years)	10.51 (6.52 to 15.01)	10.91 (6.21 to 15.56)	10.29 (6.02 to 15.79)	0.167	0.647	0.071
Weight (kg)	39.55 (18.60 to 89.30)	36.5 (15.80 to 65.50)	28.60 (16.90 to 62)	0.096	0.001	0.001
Height (cm)	147 (110 to 168.40)	143.50 (110 to 175)	135 (108 to 181)	0.613	0.021	0.007
SII (mmHg/L)	461.59 (255.60 to 857.30)	506.60 (267 to 1051.10)	467.15 (236.60 to 1179.30)	0.101	0.798	0.23
SIII (mmHg/L)	12.31 (4.50 to 27.70)	17.55 (5.60 to 51.90)	27.86 (6.50 to 69.80)	<0.001	<0.001	<0.001
SII/TV	1.17 (0.35 to 3.42)	1.44 (0.21 to 4.82)	1.41 (0.32 to 5.44)	0.043	0.203	0.688
SIII/TV	0.03 (0.004 to 0.12)	0.05 (0.004 to 0.25)	0.08 (0.012 to 0.37)	<0.001	<0.001	0.001
KPIv	2.53 (1.25 to 4.09)	3.41 (1.79 to 10.78)	4.96 (1.63 to 16.94)	<0.001	<0.001	<0.001
FEV₁ (predicted %)	101.27 (74.64 to 126.70)	81.71 (26.32 to 121.90)	82.01 (35.42 to 113.56)	<0.001	<0.001	0.741
FEV₁ (Z-score)	0.11 (-2.12 to 2.34)	-1.57 (-5.79 to 1.77)	-1.47 (-5.27 to 1.14)	<0.001	<0.001	0.789
FVC (predicted %)	97.15 (82.48 to 118.77)	90.42 (51.63 to 148.01)	86.40 (53.05 to 116.77)	0.001	<0.001	0.051
FVC (Z-score)	-0.24 (-1.51 to 1.56)	-0.82 (-4.27 to 3.82)	-1.17 (-4.16 to 1.33)	0.001	<0.001	0.062
FEV₁/FVC (predicted %)	104.19 (89.26 to 112.26)	90.43 (50.52 to 112.63)	95.79 (67.06 to 109.03)	<0.001	<0.001	0.011
FEV₁/FVC (Z-score)	0.75 (-1.49 to 2.48)	-1.31 (-4.44 to 2.12)	-0.60 (-3.55 to 1.46)	<0.001	<0.001	0.013
FEF_25-75% (predicted %)	107.59 (35.48 to 142.48)	62.79 (8.75 to 137.55)	67.79 (12.23 to 129.85)	<0.001	<0.001	0.294
FEF_25-75% (Z-score)	0.34 (-3.31 to 1.85)	-1.79 (-6.28 to 1.59)	-1.60 (-5.83 to 1.24)	<0.001	<0.001	0.203
Individuals with normal spirometry values
Markers	HCG (n = 39)	AAG (n = 57)	CFG (n = 28)	HCG versus AAG (p-value)	HCG versus CFG (p-value)	AAG versus CFG (p-value)
SIII (mmHg/L)	12.31 (4.53 to 27.73)	16.88 (6.78 to 37.85)	21.77 (6.46 to 56.82)	<0.001	<0.001	0.065
SIII/TV	0.03 (0.004 to 0.13)	0.05 (0.01 to 0.18)	0.08 (0.01 to 0.32)	<0.001	0.001	0.350
KPIv	2.55 (1.25 to 4.09)	3.14 (1.79 to 10.78)	4.47 (1.63 to 14.33)	0.002	<0.001	0.003
FEV₁ (predicted %)	101.41 (84.27 to 126.70)	90.93 (80.23 to 121.90)	92.78 (80.65 to 113.56)	<0.001	0.003	0.779
FEV₁ (Z-score)	0.13 (-1.30 to 2.34)	-0.75 (-1.67 to 1.77)	-0.61 (-1.67 to 1.14)	<0.001	0.003	0.793
FVC (predicted %)	97.25 (82.48 to 118.77)	95.79 (80.14 to 148.01)	92.15 (81.70 to 112.46)	0.389	0.069	0.266
FVC (Z-score)	-0.23 (-1.51 to 1.56)	-0.37 (-1.65 to 3.82)	-0.67 (-1.57 to 1)	0.389	0.071	0.282
FEV₁/FVC (predicted %)	104.31 (90.67 to 112.26)	95.23 (80.58 to 112.63)	99.67 (90.30 to 109.03)	<0.001	0.005	0.006
FEV₁/FVC (Z-score)	0.77 (-1.27 to 2.48)	-0.69 (-2.32 to 2.12)	-0.06 (-1.37 to 1.46)	<0.001	0.005	0.007
FEF_25-75% (predicted %)	108.20 (63.49 to 142.48)	82.61 (63.28 to 135.56)	90.56 (72.94 to 129.85)	<0.001	0.221	0.081
FEF_25-75% (Z-score)	0.35 (-1.64 to 1.85)	-0.78 (-1.64 to 1.59)	-0.42 (-1.19 to 1.24)	<0.001	0.204	0.069
Area under the curve for volumetric capnography and spirometry between control group (HCG; n = 40), group of patients with asthma (AAG; n = 103) and group of patients with cystic fibrosis (CFG; n = 53)
Markers	HCG versus CFG	HCG versus CFG	AAG versus CFG	HCG versus AAG (p-value)	HCG versus CFG (p-value)	AAG versus CFG (p-value)
SIII (mmHg/L)	0.782^a a A smaller result indicates a positive test.	0.899^a a A smaller result indicates a positive test.	0.722^a a A smaller result indicates a positive test.	<0.001	<0.001	<0.001
SIII/TV	0.732^a a A smaller result indicates a positive test.	0.831^a a A smaller result indicates a positive test.	0.660^a a A smaller result indicates a positive test.	<0.001	<0.001	0.001
KPIv	0.737^a a A smaller result indicates a positive test.	0.927^a a A smaller result indicates a positive test.	0.763^a a A smaller result indicates a positive test.	<0.001	<0.001	<0.001
FEV₁ (predicted %)	0.836^b b A higher result indicates a positive test.	0.836^b b A higher result indicates a positive test.	0.516^b b A higher result indicates a positive test.	<0.001	<0.001	0.741
FEV₁ (Z-score)	0.839^b b A higher result indicates a positive test.	0.838^b b A higher result indicates a positive test.	0.513^b b A higher result indicates a positive test.	<0.001	<0.001	0.789
FVC (predicted %)	0.685^b b A higher result indicates a positive test.	0.756^b b A higher result indicates a positive test.	0.596^b b A higher result indicates a positive test.	0.001	<0.001	0.051
FVC (Z-score)	0.686^b b A higher result indicates a positive test.	0.754^b b A higher result indicates a positive test.	0.591^b b A higher result indicates a positive test.	0.001	<0.001	0.062
FEV₁/FVC (predicted %)	0.863^b b A higher result indicates a positive test.	0.799^b b A higher result indicates a positive test.	0.624^a a A smaller result indicates a positive test.	<0.001	<0.001	0.011
FEV₁/FVC (Z-score)	0.864^b b A higher result indicates a positive test.	0.800^b b A higher result indicates a positive test.	0.622^a a A smaller result indicates a positive test.	<0.001	<0.001	0.013
FEF_25-75% (predicted %)	0.839^b b A higher result indicates a positive test.	0.778^b b A higher result indicates a positive test.	0.551^a a A smaller result indicates a positive test.	<0.001	<0.001	0.294
FEF_25-75% (Z-score)	0.843^b b A higher result indicates a positive test.	0.780^b b A higher result indicates a positive test.	0.562^a a A smaller result indicates a positive test.	<0.001	<0.001	0.203
Patients with normal spirometry. HCG (n = 39), AAG (n = 57) and CFG (n = 28)
Markers	HCG versus CFG	HCG versus CFG	AAG versus CFG	HCG versus AAG (p-value)	HCG versus CFG (p-value)	AAG versus CFG (p-value)
SIII (mmHg/L)	0.768^a a A smaller result indicates a positive test.	0.822^a a A smaller result indicates a positive test.	0.623^a a A smaller result indicates a positive test.	<0.001	<0.001	0.065
SIII/TV	0.730^a a A smaller result indicates a positive test.	0.742^a a A smaller result indicates a positive test.	0.563^a a A smaller result indicates a positive test.	<0.001	0.001	0.350
KPIv	0.686^a a A smaller result indicates a positive test.	0.866^a a A smaller result indicates a positive test.	0.702^a a A smaller result indicates a positive test.	0.002	<0.001	0.003
FEV₁ (predicted %)	0.726^b b A higher result indicates a positive test.	0.712^b b A higher result indicates a positive test.	0.519^b b A higher result indicates a positive test.	<0.001	0.003	0.779
FEV₁ (Z-score)	0.732^b b A higher result indicates a positive test.	0.717^b b A higher result indicates a positive test.	0.518^b b A higher result indicates a positive test.	<0.001	0.003	0.793
FVC (predicted %)	0.552^b b A higher result indicates a positive test.	0.631^b b A higher result indicates a positive test.	0.575^b b A higher result indicates a positive test.	0.389	0.069	0.266
FVC (Z-score)	0.552^b b A higher result indicates a positive test.	0.630^b b A higher result indicates a positive test.	0.572^b b A higher result indicates a positive test.	0.389	0.071	0.282
FEV₁/FVC (predicted %)	0.814^b b A higher result indicates a positive test.	0.702^b b A higher result indicates a positive test.	0.683^a a A smaller result indicates a positive test.	<0.001	0.005	0.006
FEV₁/FVC (Z-score)	0.815^b b A higher result indicates a positive test.	0.701^b b A higher result indicates a positive test.	0.681^a a A smaller result indicates a positive test.	<0.001	0.005	0.007
FEF_25a75% (predicted %)	0.740^b b A higher result indicates a positive test.	0.596^b b A higher result indicates a positive test.	0.634^a a A smaller result indicates a positive test.	<0.001	0.221	0.081
FEF_25a75% (Z-score)	0.745^b b A higher result indicates a positive test.	0.600^b b A higher result indicates a positive test.	0.640^a a A smaller result indicates a positive test.	<0.001	0.204	0.069

Brasil