Changes in ventilatory capacity, exercise capacity, and pulmonary blood flow after lobectomy in patients with lung cancer - which lobectomy has the most loss in exercise capacity?

Background: Correction of tetralogy of Fallot (cTOF) often results in pulmonary valve pathology and right ventricular (RV) dysfunction. Reduced exercise capacity in cTOF patients cannot be explained by these findings alone. We aimed to explore why cTOF patients exhibit impaired exercise capacity with the aid of a comprehensive cardiopulmonary exercise testing (CPET) and real-time cardiovascular magnetic resonance exercise testing (CMR-ET) protocol. Methods: Three cTOF patients and 35 matched healthy controls underwent CPET and CMR-ET in a prospective case-control study. Real-time steady-state free precession cine and phase-contrast sequences were obtained during incremental supine in-scanner cycling at 50, 70, and 90 W. RV and left ventricle (LV) volumes and pulmonary blood flow (Qp) were calculated. Differences of CPET and CMR-ET between cTOF versus controls and correlations between CPET and CMR-ET parameters in cTOF were evaluated statistically for all CMR exercise levels using Mann-Whitney U and Spearman rank-order correlation tests. Results: CPET capacity was significantly lower in cTOF than in controls. cTOF patients exhibited not only significantly reduced Qp and RV function but also lower LV function on CMR-ET. Higher CPET values in cTOF correlated with higher Qp (Qp 90 W versus carbon dioxide ventilatory equivalent %: R =−0.519, P <0.05), higher LV–end-diastolic volume indexed to body surface area (LV–end-diastolic volume indexed to body surface area at 50 W versus oxygen uptake in % at maximum exercise on CPET R =0.452, P <0.05), and change in LV ejection fraction (EF; LV-EF at 90 W versus Watt %: r =−0.463, P <0.05). No correlation was found with regard to RV-EF. Significant RV-LV interaction was observed during CMR-ET (RV-EF versus LV-EF at 50 W and 70 W: r =0.66, P <0.02 and r =0.52, P <0.05, respectively). Conclusions: Impaired exercise capacity in cTOF resulted from a reduction in not only RV, but also LV function. cTOF with good exercise capacity on CPET demonstrated higher LV reserve and pulmonary blood flow during incremental CMR-ET. Apart from RV parameters, CMR-ET–derived LV function could be a valuable tool to stratify cTOF patients for pulmonary valve replacement.

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Breathing training improves exercise capacity in patients with tetralogy of Fallot: a randomised trial

Heart ◽

10.1136/heartjnl-2020-318574 ◽

2021 ◽

pp. heartjnl-2020-318574

Author(s):

Julia Hock ◽

Julia Remmele ◽

Renate Oberhoffer ◽

Peter Ewert ◽

Alfred Hager

Keyword(s):

Blood Flow ◽

Tetralogy Of Fallot ◽

Exercise Capacity ◽

Pulmonary Blood Flow ◽

Randomised Trial ◽

Cardiopulmonary Exercise Testing ◽

Young Patients ◽

Control Group ◽

Lung Volumes ◽

Breathing Training

ObjectivePatients with tetralogy of Fallot (ToF) have limited pulmonary blood flow before corrective surgery and ongoing dysfunction of the pulmonary valve and right ventricle throughout life leading to lower exercise capacity and lung volumes in many patients. Inhalation training can increase lung volumes, improve pulmonary blood flow and consequently exercise capacity. This study tests whether home-based daily breathing training improves exercise capacity and lung volumes.MethodsFrom February 2017 to November 2018, 60 patients (14.7±4.8 years, 39% female) underwent spirometry (forced vital capacity (FVC); forced expiratory volume in 1 s (FEV1)), cardiopulmonary exercise testing (peak oxygen uptake (peak V˙O2)) and breathing excursion measurement. They were randomised into immediate breathing exercise or control group (CG) and re-examined after 6 months. The CG started their training afterwards and were re-examined after further 6 months. Patients trained with an inspiratory volume-oriented breathing device and were encouraged to exercise daily. The primary endpoint of this study was the change in peak V˙O2. Results are expressed as mean±SEM (multiple imputations).ResultsIn the first 6 months (intention to treat analysis), the training group showed a more favourable change in peak V˙O2 (Δ0.5±0.6 vs −2.3±0.9 mL/min/kg, p=0.011), FVC (Δ0.18±0.03 vs 0.08±0.03 L, p=0.036) and FEV1 (Δ0.14±0.03 vs −0.00±0.04 L, p=0.007). Including the delayed training data from the CG (n=54), this change in peak V˙O2 correlated with self-reported weekly training days (r=0.282, p=0.039).ConclusionsDaily inspiratory volume-oriented breathing training increases dynamic lung volumes and slows down deconditioning in peak V˙O2 in young patients with repaired ToF.

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