Ventilatory limitations are not associated with dyspnea on exertion or reduced aerobic fitness in pectus excavatum (original) (raw)
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Diminished pulmonary function in pectus excavatum: from denying the problem to finding the mechanism
Annals of Cardiothoracic Surgery, 2016
Background: Recently, technical improvement in the ability to measure lung function and the severity of chest deformity have enabled progress in understanding the mechanism of limitations of lung function in pectus excavatum. Methods: After establishing that most patients with pectus excavatum do have symptoms of exercise intolerance, easy fatigability, and shortness of breath with exertion, lung function has been evaluated by a variety of methods in different centers. Spirometry, plethysmography, exercise testing, oculo electronic plethysmography, and imaging methods have been used to assess lung function in pectus excavatum and its response to surgery. Results: Not all patients with pectus excavatum have subnormal static pulmonary function testing; some have above-average values. However, in more than 1500 adult and pediatric surgical patients with anatomically severe pectus excavatum at a single center, the bell curve of FVC, FEV1, and FEF 25-75 is shifted to significantly lower values in pectus excavatum. The curve is shifted to higher values after operation by approximately one standard deviation. Previous work has demonstrated that patients with more anatomically severe pectus excavatum are more likely to have diminished PFT's. A mechanism for this effect is seen by oculo electronic plethysmography, which demonstrates that the depressed portion of the chest does not move on respiration. After Nuss procedure, the chest wall motion used to create suction to draw air into the lungs is indistinguishable from that of persons with a normal chest, and the intrathoracic volume is markedly increased. Conclusions: Pectus excavatum is accompanied in most patients by diminished static pulmonary function. Correction by Nuss procedure results in improvement in chest wall motion; this improvement in the thoracic bellows action is accompanied by improvement in pulmonary function testing.
Journal of medical case reports, 2011
Introduction: Pectus excavatum is the most common congenital deformity of the anterior chest wall that, under certain conditions, may pose functional problems due to cardiopulmonary compromise and exercise intolerance. Case presentation: We present the case of an otherwise physically-adept 21-year-old Chinese sportsman with idiopathic pectus excavatum, whose symptoms manifested only on bearing a loaded body vest and backpack during physical exercise. Corroborative objective evidence was obtained via load-stressed pulmonary function testing, which demonstrated restrictive lung function. Conclusion: This report highlights the possible detrimental synergism of thoracic load stress and pectus excavatum on cardiopulmonary function. Thoracic load-stressed pulmonary function testing provides objective evidence in support of such a synergistic relationship.
Journal of the American College of Surgeons, 2013
BACKGROUND: A multicenter study of pectus excavatum was described previously. This report presents our final results. STUDY DESIGN: Patients treated surgically at 11 centers were followed prospectively. Each underwent a preoperative evaluation with CT scan, pulmonary function tests, and body image survey. Data were collected about associated conditions, complications, and perioperative pain. One year after treatment, patients underwent repeat chest CT scan, pulmonary function tests, and body image survey. A subset of 50 underwent exercise pulmonary function testing.
BMJ Open Respiratory Research, 2021
Cohort studies of patients with pectus excavatum have inadequately characterised exercise dysfunction experienced. Cardiopulmonary exercise test data were delineated by maximal oxygen uptake values >80%, which was tested to examine whether patterns of exercise physiology were distinguished.MethodsSeventy-two patients considered for surgical treatment underwent assessment of pulmonary function and exercise physiology with pulmonary function tests and cardiopulmonary exercise test between 2006 and 2019. Seventy who achieved a threshold respiratory gas exchange ratio of >1.1 were delineated by maximal oxygen uptake >80%, (group A, n=33) and <80% (group B, n=37) and comparison of constituent physiological parameters performed.ResultsThe cohort was 20.8 (±SD 6.6) years of age, 60 men, with a Haller’s Index of 4.1 (±SD 1.4). Groups A and B exhibited similar demography, pulmonary function test results and Haller’s index values. Exercise test parameters of group B were lower tha...
Impact of Pectus Excavatum on Cardiopulmonary Function
The Annals of Thoracic Surgery, 2018
Background. Pectus excavatum is classified using the Haller Index (HI) or the Correction Index. However, no correlation between the HI and CI and cardiopulmonary impairment has been described in detail. Methods. This prospective cohort study included 99 otherwise healthy patients with pectus excavatum who underwent cardiopulmonary exercise testing and magnetic resonance imaging at inspiration and expiration to correlate cardiopulmonary function with the grade of thoracic dysmorphia. Results. Probands with an HI exceeding 3.25 had first an increase in heart rate at anaerobic threshold (from 148.0 ± 16.0 beats/min to 155.9 ± 15.0 beats/min, p [ 0.036), with an HI of more than 3.6 a reduction in oxygen pulse at anaerobic threshold (from 10.7 ± 2.6 mL/ beat to 9.3 ± 2.9 mL/beat, p [ 0.017), with an HI exceeding 3.8 a reduction of maximum oxygen pulse (from 13.9 ± 3.4 mL/beat to 11.9 ± 3.7 mL/beat,
Exercise improvement after pectus excavatum repair is not related to chest wall function
European Journal of Cardio-Thoracic Surgery, 2014
OBJECTIVES: In patients undergoing corrective surgery for pectus excavatum, there is evidence of improvement in cardiopulmonary function. It is unclear how much of this improvement is attributable to improved chest wall function. Thus, we observed changes in chest wall function in response to an incremental load exercise pre-and postoperatively.
Cardiopulmonary effects of closed repair of pectus excavatum
Journal of Pediatric Surgery, 2003
Increasing numbers of patients with pectus excavatum defects are presenting for operative repair. Studies that follow-up with patients after open repair have found a decrease in pulmonary function with some improvement in cardiac output and exercise tolerance; however, these effects have not been examined systematically after closed or Nuss repair of pectus excavatum. This study examined the early postoperative effects of closed repair of pectus on pulmonary function, exercise tolerance, and cardiac function. Patients were followed up prospectively after initial evaluation for operation. All patients underwent preoperative computed tomography (CT) scan, and pre- and postoperative (3 months) pulmonary function studies, exercise tolerance, and echocardiographic evaluation of cardiac function. Eleven patients underwent evaluation. Preoperative CT index was 4.1 +/- 0.9. Patients reported an improvement in subjective postoperative exercise tolerance (4.1 +/- 0.7; maximal, + 5). Pulmonary function studies (FVC and vital capacity) were significantly reduced at 3 months postsurgery: change in FVC, -0.67 +/- 0.92 L and VC, -0.5 +/- 0.72 L. Similarly, VO2 max was reduced: preoperative, 35.6 +/- 1.5 versus postoperative, 29.1 +/- 11.9 L/kg/min. Cardiac function was significantly improved postoperation (stroke volume preoperative, 61.6 +/- 25 versus 77.5 +/- 23 mL postoperative). All comparisons had a P value less than.05 by Student&amp;amp;amp;amp;amp;#39;s paired t test. These results show that closed repair of pectus excavatum is associated with a subjective improvement in exercise tolerance, which is paralleled by an increase in cardiac function and a decline in pulmonary function. These findings support the use of closed repair of pectus excavatum in patients who complain of subjective shortness of breath; further study is required to delineate the long-term cardiopulmonary implications after closed repair.
Why is exercise capacity reduced in subjects with pectus excavatum?
The Journal of Pediatrics, 2000
Anaerobic threshold FSTI Fronto-sagital thoracic index PE Pectus excavatum SV Stroke volume V'O 2 Oxygen uptake WR Work rate Background: Exercise capacity is often limited in subjects with pectus excavatum (PE), but the mechanism is unknown.