Your search keyword '"Sheel AW"' showing total 19 results

1. Child obesity and fitness levels among Kenyan and Canadian children from urban and rural environments: A KIDS-CAN Research Alliance Study.

Author

Adamo KB, Sheel AW, Onywera V, Waudo J, Boit M, and Tremblay MS

Published

2011

2. The effect of proportional assist ventilation on the electrical activity of the human diaphragm during exercise.

Author

Gerson EAM, Dominelli PB, Leahy MG, Kipp S, Guenette JA, Archiza B, and Sheel AW

Subjects

Humans, Male, Female, Respiration, Artificial, Respiration, Exercise, Diaphragm, Interactive Ventilatory Support

Abstract

New Findings: What is the central question of this study? What is the effect of lowering the normally occurring work of breathing on the electrical activity and pressure generated by the diaphragm during submaximal exercise in healthy humans? What is the main finding and its importance? Ventilatory assist during exercise elicits a proportional lowering of both the work performed by the diaphragm and diaphragm electrical activity. These findings have implications for exercise training studies using proportional assist ventilation to reduce diaphragm work in patients with cardiopulmonary disease., Abstract: We hypothesized that when a proportional assist ventilator (PAV) is applied in order to reduce the pressure generated by the diaphragm, there would be a corresponding reduction in electrical activity of the diaphragm. Healthy participants (five male and four female) completed an incremental cycle exercise test to exhaustion in order to calculate workloads for subsequent trials. On the experimental day, participants performed submaximal cycling, and three levels of assisted ventilation were applied (low, medium and high). Ventilatory parameters, pulmonary pressures and EMG of the diaphragm (EMG di ) were obtained. To compare the PAV conditions with spontaneous breathing intervals, ANOVA procedures were used, and significant effects were evaluated with a Tukey-Kramer test. Significance was set at P < 0.05. The work of breathing was not different between the lowest level of unloading and spontaneous breathing (P = 0.151) but was significantly lower during medium (25%, P = 0.02) and high (36%, P < 0.001) levels of PAV. The pressure-time product of the diaphragm (PTP di ) was lower across PAV unloading conditions (P < 0.05). The EMG di was significantly lower in medium and high PAV conditions (P = 0.035 and P < 0.001, respectively). The mean reductions of EMG di with PAV unloading were 14, 22 and 39%, respectively. The change in EMG di for a given lowering of PTP di with the PAV was significantly correlated (r = 0.61, P = 0.01). Ventilatory assist during exercise elicits a reduction in the electrical activity of the diaphragm, and there is a proportional lowering of the work of breathing. Our findings have implications for exercise training studies using assisted ventilation to reduce diaphragm work in patients with cardiopulmonary disease., (© 2022 The Authors. Experimental Physiology published by John Wiley & Sons Ltd on behalf of The Physiological Society.)

Published

2023

3. Reply to Beltrami.

Author

Ramsook AH, Peters CM, Leahy MG, Archiza B, Mitchell RA, Jasinovic T, Koehle MS, Guenette JA, and Sheel AW

Subjects

Algorithms

Published

2021

4. Near-infrared spectroscopy measures of sternocleidomastoid blood flow during exercise and hyperpnoea.

Author

Ramsook AH, Peters CM, Leahy MG, Archiza B, Mitchell RA, Jasinovic T, Koehle MS, Guenette JA, and Sheel AW

Subjects

Adult, Blood Flow Velocity physiology, Hemodynamics physiology, Humans, Hyperventilation metabolism, Indocyanine Green metabolism, Male, Oxygen Consumption physiology, Quadriceps Muscle metabolism, Quadriceps Muscle physiology, Respiration, Respiratory Muscles metabolism, Respiratory Muscles physiology, Spectroscopy, Near-Infrared methods, Exercise physiology, Hyperventilation physiopathology, Quadriceps Muscle blood supply, Regional Blood Flow physiology, Respiratory Muscles blood supply

Abstract

New Findings: What is the central question of this study? How does sternocleidomastoid blood flow change in response to increasing ventilation and whole-body exercise intensity? What is the main finding and its importance? Sternocleidomastoid blood flow increased with increasing ventilation. For a given ventilation, sternocleidomastoid blood flow was lower during whole-body exercise compared to resting hyperpnoea. These findings suggest that locomotor muscle work exerts an effect on respiratory muscle blood flow that can be observed in the sternocleidomastoid., Abstract: Respiratory muscle work influences the distribution of blood flow during exercise. Most studies have focused on blood flow to the locomotor musculature rather than the respiratory muscles, owing to the complex anatomical arrangement of respiratory muscles. The purpose of this study was to examine how accessory respiratory (i.e. sternocleidomastoid, and muscles in the intercostal space) muscle blood flow changes in response to locomotor muscle work. Seven men performed 5 min bouts of constant load cycling exercise trials at 30%, 60% and 90% of peak work rate in a randomized order, followed by 5 min bouts of voluntary hyperpnoea (VH) matching the ventilation achieved during each exercise (EX) trial. Blood-flow index (BFI) of the vastus lateralis, sternocleidomastoid (SCM) and seventh intercostal space (IC) were estimated using near-infrared spectroscopy and indocyanine green and expressed relative to resting levels. BFI SCM was greater during VH compared to EX (P = 0.002) and increased with increasing exercise intensity (P = 0.036). BFI SCM reached 493 ± 219% and 301 ± 215% rest during VH and EX at 90% peak work rate, respectively. BFI IC increased to 242 ± 178% and 210 ± 117% rest at 30% peak work rate during VH and EX, respectively. No statistically significant differences in BFI IC were observed with increased work rate during VH or EX (both P > 0.05). Moreover, there was no observed difference in BFI IC between conditions (P > 0.05). BFI SCM was lower for a given minute ventilation during EX compared to VH, suggesting that accessory respiratory muscle blood flow is influenced by whole-body exercise., (© 2020 The Authors. Experimental Physiology © 2020 The Physiological Society.)

Published

2020

5. The hyperpnoea of exercise in health: Respiratory influences on neurovascular control.

Author

Sheel AW, Taylor JL, and Katayama K

Subjects

Cardiac Output physiology, Humans, Muscle Fatigue physiology, Muscle, Skeletal physiology, Regional Blood Flow physiology, Exercise physiology, Hyperventilation physiopathology, Respiratory Muscles physiology, Work of Breathing physiology

Abstract

New Findings: What is the topic of this review? Elevated demand is placed on the respiratory muscles during whole-body exercise-induced hyperpnoea. What is the role of elevated demand in neural modulation of cardiovascular control in respiratory and locomotor skeletal muscle, and what are the mechanisms involved? What advances does it highlight? There is a sympathetic restraint of blood flow to locomotor muscles during near-maximal exercise, which might function to maintain blood pressure. During submaximal exercise, respiratory muscle blood flow might be also be reduced if ventilatory load is sufficiently high. Methodological advances (near-infrared spectroscopy with indocyanine green) confirm that blood flow is diverted away from respiratory muscles when the work of breathing is alleviated., Abstract: It is known that the respiratory muscles have a significant increasing oxygen demand in line with hyperpnoea during whole-body endurance exercise and are susceptible to fatigue, in much the same way as locomotor muscles. The act of ventilation can itself be considered a form of exercise. The manipulation of respiratory load at near-maximal exercise alters leg blood flow significantly, demonstrating a competitive relationship between different skeletal muscle vascular beds to perfuse both sets of muscles adequately with a finite cardiac output. In recent years, the question has moved towards whether this effect exists during submaximal exercise, and the use of more direct measurements of respiratory muscle blood flow itself to confirm assumptions that uphold the concept. Evidence thus far has shown that there is a reciprocal effect on blood flow redistribution during ventilatory load manipulation observed at the respiratory muscles themselves and that the effect is observable during submaximal exercise, where active limb blood flow was reduced in conditions that simulated a high work of breathing. This has clinical applications for populations with respiratory disease and heart failure, where the work of breathing is remarkably high, even during submaximal efforts., (© 2020 The Authors. Experimental Physiology © 2020 The Physiological Society.)

Published

2020

6. Modelling the effects of age and sex on the resistive and viscoelastic components of the work of breathing during exercise.

Author

Molgat-Seon Y, Dominelli PB, Guenette JA, and Sheel AW

Subjects

Aged, Aged, 80 and over, Exercise Test methods, Female, Humans, Lung physiology, Male, Middle Aged, Pulmonary Ventilation physiology, Respiration, Exercise physiology, Respiratory Mechanics physiology, Work of Breathing physiology

Abstract

New Findings: What is the central question of this study? What is the effect of age and sex on the resistive and viscoelastic components of work of breathing (W b ) during exercise? What is the main finding and its importance? The resistive and viscoelastic components of W b were higher in older adults, regardless of sex. The resistive, but not viscoelastic, component of W b was higher in females than in males, regardless of age. These findings contribute to improving our understanding of the effects of ageing and sex on the mechanical ventilatory response to exercise., Abstract: Healthy ageing and biological sex each affect the work of breathing (W b ) for a given minute ventilation ( V ̇ E ). Age-related structural changes to the respiratory system lead to an increase in both the resistive and viscoelastic components of W b ; however, it is unclear whether healthy ageing differentially alters the mechanics of breathing in males and females. We analysed data from 22 older (60-80 years, n = 12 females) and 22 younger (20-30 years, n = 11 females) males and females that underwent an incremental cycle exercise test to exhaustion. V ̇ E and W b were assessed at rest and throughout exercise. W b - V ̇ E data for each participant were fitted to a non-linear equation (i.e. W b  = a V ̇ E 3 + b V ̇ E 2 ) that partitions W b into resistive (i.e. a V ̇ E 3 ) and viscoelastic (i.e. b V ̇ E 2 ) components. We then modelled the effects of healthy ageing and biological sex on each component of W b . Overall, the model fit was excellent (r 2 : 0.99 ± 0.01). There was a significant main effect of age and sex on the resistive component of W b (both P < 0.05), and a significant main effect of age (P < 0.001), but not sex (P = 0.309), on the viscoelastic component of W b . No significant interactions between age and sex on a V ̇ E 3 or b V ̇ E 2 were noted (both P > 0.05). Our findings indicate that during exercise: (i) the higher total W b in females relative to males is due to a higher resistive, but not viscoelastic, component of W b , and (ii) regardless of sex, the higher W b in older adults relative to younger adults is due to higher resistive and viscoelastic components of W b ., (© 2019 The Authors. Experimental Physiology © 2019 The Physiological Society.)

Published

2019

7. Breathing during exercise: There is no such thing as a free lunch.

Author

Sheel AW and Dominelli PB

Subjects

Adolescent, Endurance Training, Humans, Obesity, Respiratory Muscles, Exercise Tolerance, Walking

Published

2019

8. Work of breathing influences muscle sympathetic nerve activity during semi-recumbent cycle exercise.

Author

Dominelli PB, Katayama K, Vermeulen TD, Stuckless TJR, Brown CV, Foster GE, and Sheel AW

Subjects

Adult, Bicycling physiology, Esophagus physiology, Female, Hemodynamics, Humans, Male, Oxygen Consumption, Respiratory Mechanics, Young Adult, Exercise physiology, Sympathetic Nervous System physiology, Work of Breathing

Abstract

Reducing the work of breathing during exercise improves locomotor muscle blood flow and reduces diaphragm and locomotor muscle fatigue and is thought to be the result of a sympathetically mediated reflex., Aim: The aim of this study was to assess muscle sympathetic nerve activity (MSNA) when the work of breathing is experimentally lowered during dynamic exercise., Methods: Healthy subjects (n = 12; age = 29 ± 9 years) performed semi-recumbent cycling trials at 40%, 60%, and 80% of peak workload. Exercise trials consisted of spontaneous breathing, reduced work of breathing (proportional assist ventilator), followed by further spontaneous breathing (post-ventilator). MSNA was recorded from the median nerve., Results: There was no difference in work of breathing between PAV and post-PAV at 40% peak work. At 60% peak work, the ventilator significantly (P < 0.05) reduced work of breathing (103 ± 39 vs 144 ± 47 J min -1 ), sympathetic nerve activity (35 ± 5 vs 42 ± 8 burst min -1 ), and V ˙ O 2 (2.4 ± 0.5 vs 2.6 ± 0.5 L min -1 ) without influencing ventilation (86 ± 9 vs 82 ± 10 L min -1 ; P > 0.05), for PAV and post-PAV respectively. During 80% peak work (n = 8), the ventilator significantly (P < 0.05) reduced work of breathing (235 ± 110 vs. 361 ± 150 J min -1 ), MSNA (48 ± 7 vs 54 ± 11 burst min -1 ), and V ˙ O 2 (2.9 ± 0.6 vs 3.2 ± 0.7 L min -1 ) but not ventilation (121 ± 20 vs 123 ± 20 L min -1 ; P > 0.05), for PAV and post-PAV respectively. There was a significant relationship between MSNA and V ˙ O 2 (P < 0.0001) with a significant interaction due to the ventilator (P < 0.05)., Conclusion: Lowering the normally occurring work of breathing during exercise results in commensurate reductions in MSNA. Our findings provide evidence of a sympathetically mediated vasoconstrictor effect emanating from respiratory muscles during exercise., (© 2018 Scandinavian Physiological Society. Published by John Wiley & Sons Ltd.)

Published

2019

9. Effect of increased inspiratory muscle work on blood flow to inactive and active limbs during submaximal dynamic exercise.

Author

Katayama K, Goto K, Shimizu K, Saito M, Ishida K, Zhang L, Shiozawa K, and Sheel AW

Subjects

Adult, Arterial Pressure physiology, Exercise Test methods, Femoral Artery metabolism, Femoral Artery physiology, Humans, Inhalation physiology, Knee physiology, Male, Muscle Fatigue physiology, Muscle, Skeletal metabolism, Oxygen metabolism, Reflex physiology, Respiration, Respiratory Muscles metabolism, Rest physiology, Sympathetic Nervous System metabolism, Sympathetic Nervous System physiology, Vascular Resistance physiology, Young Adult, Exercise physiology, Extremities physiology, Muscle, Skeletal physiology, Regional Blood Flow physiology, Respiratory Muscles physiology, Work of Breathing physiology

Abstract

New Findings: What is the central question of this study? Increased respiratory muscle activation is associated with neural and cardiovascular consequences via the respiratory muscle metaboreflex. Does increased sympathetic vasoconstriction originating from the respiratory musculature elicit a reduction in blood flow to an inactive limb in order to maintain blood flow to an active limb? What is the main finding and its importance? Arm blood flow was reduced whereas leg blood flow was preserved during mild leg exercise with inspiratory resistance. Blood flow to the active limb is maintained via sympathetic control of blood flow redistribution when the respiratory muscle-induced metaboreflex is activated., Abstract: The purpose of this study was to elucidate the effect of increasing inspiratory muscle work on blood flow to inactive and active limbs. Healthy young men (n = 10, 20 ± 2 years of age) performed two bilateral dynamic knee-extension and knee-flexion exercise tests at 40% peak oxygen uptake for 10 min. The trials consisted of spontaneous breathing for 5 min followed by voluntary hyperventilation either with or without inspiratory resistance for 5 min (40% of maximal inspiratory mouth pressure, inspiratory duty cycle of 50% and a breathing frequency of 40 breaths min -1 ). Mean arterial blood pressure was acquired using finger photoplethysmography. Blood flow in the brachial artery (inactive limb) and in the femoral artery (active limb) were monitored using Doppler ultrasound. Mean arterial blood pressure during exercise was higher (P < 0.05) with inspiratory resistance (121 ± 7 mmHg) than without resistance (99 ± 5 mmHg). Brachial artery blood flow increased during exercise without inspiratory resistance (120 ± 31 ml min -1 ) compared with the resting level, whereas it was attenuated with inspiratory resistance (65 ± 43 ml min -1 ). Femoral artery blood flow increased at the onset of exercise and was maintained throughout exercise without inspiratory resistance (2576 ± 640 ml min -1 ) and was unchanged when inspiratory resistance was added (2634 ± 659 ml min -1 ; P > 0.05). These results suggest that sympathetic control of blood redistribution to active limbs is facilitated, in part, by the respiratory muscle-induced metaboreflex., (© 2018 The Authors. Experimental Physiology © 2018 The Physiological Society.)

Published

2019

10. Premature birth affects the degree of airway dysanapsis and mechanical ventilatory constraints.

Author

Duke JW, Gladstone IM, Sheel AW, and Lovering AT

Subjects

Gestational Age, Humans, Infant, Newborn, Pulmonary Ventilation physiology, Bronchopulmonary Dysplasia physiopathology, Forced Expiratory Volume physiology, Lung physiopathology, Premature Birth physiopathology

Abstract

New Findings: What is the central question of this study? Adult survivors of preterm birth without (PRE) and with bronchopulmonary dysplasia (BPD) have airflow obstruction at rest and significant mechanical ventilatory constraints during exercise compared with those born at full term (CON). Do PRE/BPD have smaller airways, indexed via the dysanapsis ratio, than CON? What is the main finding and its importance? The dysanapsis ratio was significantly smaller in BPD and PRE compared with CON, with BPD having the smallest dysanapsis ratio. These data suggest that airflow obstruction in PRE and BPD might be because of smaller airways than CON. Adult survivors of very preterm birth (≤32 weeks gestational age) without (PRE) and with bronchopulmonary dysplasia (BPD) have obstructive lung disease as evidenced by reduced expiratory airflow at rest and have significant mechanical ventilatory constraints during exercise. Airflow obstruction, in any conditions, could be attributable to several factors, including small airways. PRE and/or BPD could have smaller airways than their counterparts born at full term (CON) owing to a greater degree of dysanaptic airway development during the pre- and/or postnatal period. Thus, the purpose of the present study was to compare the dysanapsis ratio (DR), as an index of airway size, between PRE, BPD and CON. To do so, we calculated DR in PRE (n = 21), BPD (n = 14) and CON (n = 34) individuals and examined flow-volume loops at rest and during submaximal exercise. The DR, using multiple estimates of static recoil pressure, was significantly smaller in PRE and BPD (0.16 ± 0.05 and 0.10 ± 0.03 a.u.) compared with CON (0.22 ± 0.04 a.u.; both P < 0.001) and smallest in BPD (P < 0.001). The DR was significantly correlated with peak expiratory airflow at rest (r = 0.42; P < 0.001) and the extent of expiratory flow limitation during exercise (r = 0.60; P < 0.001). Our findings suggest that PRE/BPD might have anatomically smaller airways than CON, which might help to explain their lower expiratory airflow rate at rest and during exercise and further our understanding of the consequences of preterm birth and neonatal O 2 therapy., (© 2017 The Authors. Experimental Physiology © 2017 The Physiological Society.)

Published

2018

11. Effects of respiratory muscle work on respiratory and locomotor blood flow during exercise.

Author

Dominelli PB, Archiza B, Ramsook AH, Mitchell RA, Peters CM, Molgat-Seon Y, Henderson WR, Koehle MS, Boushel R, and Sheel AW

Subjects

Adult, Blood Flow Velocity, Female, Humans, Male, Muscle Contraction, Regional Blood Flow, Spectroscopy, Near-Infrared, Time Factors, Young Adult, Exercise physiology, Locomotion, Lung physiology, Quadriceps Muscle blood supply, Respiratory Muscles blood supply, Work of Breathing

Abstract

New Findings: What is the central question of this study? Does manipulation of the work of breathing during high-intensity exercise alter respiratory and locomotor muscle blood flow? What is the main finding and its importance? We found that when the work of breathing was reduced during exercise, respiratory muscle blood flow decreased, while locomotor muscle blood flow increased. Conversely, when the work of breathing was increased, respiratory muscle blood flow increased, while locomotor muscle blood flow decreased. Our findings support the theory of a competitive relationship between locomotor and respiratory muscles during intense exercise. Manipulation of the work of breathing (WOB) during near-maximal exercise influences leg blood flow, but the effects on respiratory muscle blood flow are equivocal. We sought to assess leg and respiratory muscle blood flow simultaneously during intense exercise while manipulating WOB. Our hypotheses were as follows: (i) increasing the WOB would increase respiratory muscle blood flow and decrease leg blood flow; and (ii) decreasing the WOB would decrease respiratory muscle blood flow and increase leg blood flow. Eight healthy subjects (n = 5 men, n = 3 women) performed a maximal cycle test (day 1) and a series of constant-load exercise trials at 90% of peak work rate (day 2). On day 2, WOB was assessed with oesophageal balloon catheters and was increased (via resistors), decreased (via proportional assist ventilation) or unchanged (control) during the trials. Blood flow was assessed using near-infrared spectroscopy optodes placed over quadriceps and the sternocleidomastoid muscles, coupled with a venous Indocyanine Green dye injection. Changes in WOB were significantly and positively related to changes in respiratory muscle blood flow (r = 0.73), whereby increasing the WOB increased blood flow. Conversely, changes in WOB were significantly and inversely related to changes in locomotor blood flow (r = 0.57), whereby decreasing the WOB increased locomotor blood flow. Oxygen uptake was not different during the control and resistor trials (3.8 ± 0.9 versus 3.7 ± 0.8 l min -1 , P > 0.05), but was lower on the proportional assist ventilator trial (3.4 ± 0.7 l min -1 , P < 0.05) compared with control. Our findings support the concept that respiratory muscle work significantly influences the distribution of blood flow to both respiratory and locomotor muscles., (© 2017 The Authors. Experimental Physiology © 2017 The Physiological Society.)

Published

2017

12. Influence of inspiratory resistive loading on expiratory muscle fatigue in healthy humans.

Author

Peters CM, Welch JF, Dominelli PB, Molgat-Seon Y, Romer LM, McKenzie DC, and Sheel AW

Subjects

Adult, Arterial Pressure physiology, Diaphragm metabolism, Diaphragm physiology, Exhalation physiology, Humans, Male, Muscle Contraction physiology, Phrenic Nerve metabolism, Phrenic Nerve physiology, Respiratory Mechanics physiology, Inhalation physiology, Muscle Fatigue physiology, Respiratory Muscles metabolism

Abstract

New Findings: What is the central question of this study? This study is the first to measure objectively both inspiratory and expiratory muscle fatigue after inspiratory resistive loading to determine whether the expiratory muscles are activated to the point of fatigue when specifically loading the inspiratory muscles. What is the main finding and its importance? The absence of abdominal muscle fatigue suggests that future studies attempting to understand the neural and circulatory consequences of diaphragm fatigue can use inspiratory resistive loading without considering the confounding effects of abdominal muscle fatigue. Expiratory resistive loading elicits inspiratory as well as expiratory muscle fatigue, suggesting parallel coactivation of the inspiratory muscles during expiration. It is unknown whether the expiratory muscles are likewise coactivated to the point of fatigue during inspiratory resistive loading (IRL). The purpose of this study was to determine whether IRL elicits expiratory as well as inspiratory muscle fatigue. Healthy male subjects (n = 9) underwent isocapnic IRL (60% maximal inspiratory pressure, 15 breaths min -1 , 0.7 inspiratory duty cycle) to task failure. Abdominal and diaphragm contractile function was assessed at baseline and at 3, 15 and 30 min post-IRL by measuring gastric twitch pressure (P ga,tw ) and transdiaphragmatic twitch pressure (P di,tw ) in response to potentiated magnetic stimulation of the thoracic and phrenic nerves, respectively. Fatigue was defined as a significant reduction from baseline in P ga,tw or P di,tw . Throughout IRL, there was a time-dependent increase in cardiac frequency and mean arterial blood pressure, suggesting activation of the respiratory muscle metaboreflex. The P di,tw was significantly lower than baseline (34.3 ± 9.6 cmH 2 O) at 3 (23.2 ± 5.7 cmH 2 O, P < 0.001), 15 (24.2 ± 5.1 cmH 2 O, P < 0.001) and 30 min post-IRL (26.3 ± 6.0 cmH 2 O, P < 0.001). The P ga,tw was not significantly different from baseline (37.6 ± 17.1 cmH 2 O) at 3 (36.5 ± 14.6 cmH 2 O), 15 (33.7 ± 12.4 cmH 2 O) and 30 min post-IRL (32.9 ± 11.3 cmH 2 O). Inspiratory resistive loading elicits objective evidence of diaphragm, but not abdominal, muscle fatigue. Agonist-antagonist interactions for the respiratory muscles appear to be more important during expiratory versus inspiratory loading., (© 2017 The Authors. Experimental Physiology © 2017 The Physiological Society.)

Published

2017

13. A proportional assist ventilator to unload respiratory muscles experimentally during exercise in humans.

Author

Dominelli PB, Henderson WR, and Sheel AW

Subjects

Female, Humans, Male, Oxygen Consumption physiology, Pressure, Respiration, Work of Breathing physiology, Exercise physiology, Respiratory Muscles physiology

Abstract

What is the central question of this study? Can a modern proportional assist ventilator (PAV) function sufficiently well to unload the respiratory muscles during exercise? What is the main finding and its importance? A PAV can be constructed with contemporary hardware and software and be used at all exercise intensities to unload the respiratory muscles by up to 70%. Previously, PAVs have allowed researchers to address many fundamental physiological problems in clinical and healthy populations, but those versions are no longer functional or available. We describe the creation of a PAV that permits researchers to use it as an experimental tool. Manipulation of the normally occurring work of breathing (WOB) during exercise can provide insights into whole-body regulatory mechanisms in clinical patients and healthy subjects. One method to reduce the WOB uses a proportional assist ventilator (PAV). Suitable commercially available units are not capable of being used during heavy exercise. This investigation was undertaken in order to create a PAV and assess the degree to which the WOB could be reduced during exercise. A PAV works by creating a positive mouth pressure (Pm ) during inspiration, which consequently reduces the WOB. Spontaneous breathing patterns can be maintained, and the amplitude of Pm is calculated using the equation of motion and predetermined proportionality constants. We generated positive Pm using a breathing apparatus consisting of rigid tubing, solenoid valves to control the airflow direction and a proportional valve connected to compressed gas. Healthy male and female subjects were able to use the PAV successfully while performing cycling exercise over a range of intensities (50-100% of maximal workload) for different durations (from 30 s to 20 min) and different protocols (constant versus progressive workload). Inspiratory WOB was reduced up to 90%, while total WOB was reduced by 70%. The greatest reduction in WOB (50-75%) occurred during submaximal exercise, but at maximal ventilations (>180 l min(-1) ) a 50% reduction was still possible. The calculated change in WOB and subsequent reduction in respiratory muscle oxygen consumption resulted in equivalent reductions in whole-body oxygen consumption. With adequate familiarization and practice, our PAV can consistently reduce the WOB across a range of exercise intensities., (© 2016 The Authors. Experimental Physiology © 2016 The Physiological Society.)

Published

2016

14. Sex differences in the physiology of exercise: an integrative perspective.

Author

Sheel AW

Subjects

Female, Humans, Male, Physiology methods, Sex Characteristics, Exercise physiology

Abstract

Video slideshow introduction to the Symposium by Symposium Speaker A. William Sheel can be found here., (© 2016 The Authors. Experimental Physiology © 2016 The Physiological Society.)

Published

2016

15. Revisiting dysanapsis: sex-based differences in airways and the mechanics of breathing during exercise.

Author

Sheel AW, Dominelli PB, and Molgat-Seon Y

Subjects

Humans, Respiration, Sex Characteristics, Exercise physiology, Pulmonary Ventilation physiology, Respiratory Mechanics physiology, Respiratory System physiopathology

Abstract

New Findings: What is the topic of this review? This review focuses on sex-based differences in the anatomy of the respiratory system, which manifest in mechanical ventilatory constraints and potentially alter the integrative response to exercise. What advances does it highlight? Recent evidence indicates that women have smaller conducting airways than men, even when matched for lung size. Consequently, women are more likely to experience mechanical ventilatory constraints to exercise hyperpnoea. Furthermore, at a given ventilation, women have a higher work and oxygen cost of breathing, both of which may lead to differences in the whole-body integrative response to dynamic exercise. Our understanding of the human ventilatory response to exercise is largely based on a historical body of literature focused primarily on male rather than female research subjects. In recent years, important sex-based differences in the anatomy of the human respiratory system have been identified; for a given lung size, women appear to have smaller-diameter conducting airways than men. The presence of such inherent differences in the tracheobronchial tree greatly affects the mechanics of airflow generation, especially during conditions of high ventilation rates, such as exercise. Data from a growing number of studies suggest that women may be more susceptible to respiratory system limitations during exercise than their male counterparts. Specifically, women are more likely to experience expiratory flow limitation and exercise-induced arterial hypoxaemia and have a higher metabolic cost of breathing for a given ventilation. Collectively, the available evidence suggests that sex differences in the ventilatory response to exercise are present and may have important ramifications for the integrated response to exercise; however, several fundamental questions remain unanswered., (© 2015 The Authors. Experimental Physiology © 2015 The Physiological Society.)

Published

2016

16. Gas density alters expiratory time constants before and after experimental lung injury.

Author

Henderson WR, Molgat-Seon Y, Dominelli PB, Brasher PM, Griesdale DE, Foster GE, Yacyshyn A, Ayas NT, and Sheel AW

Subjects

Acrylic Resins, Acute Lung Injury chemically induced, Acute Lung Injury physiopathology, Administration, Inhalation, Animals, Disease Models, Animal, Female, Gases, Lung physiopathology, Models, Biological, Specific Gravity, Sus scrofa, Time Factors, Acute Lung Injury therapy, Exhalation drug effects, Helium administration & dosage, Lung drug effects, Nitrogen administration & dosage, Respiration, Artificial methods, Sulfur Hexafluoride administration & dosage

Abstract

New Findings: What is the central question of this study? Does the induction of a model of lung injury affect the expiratory time constant (τE) in terms of either total duration or morphology? Does ventilation with gases of different densities alter the duration or morphology of τE either before or after injury? What is the main finding and its importance? The use of sulfur hexafluoride in ventilating gas mixtures lengthens total expiratory time constants before and after lung injury compared with both nitrogen and helium mixtures. Sulfur hexafluoride mixtures also decrease the difference and variability of τE between fast- and slow-emptying compartments before and after injury when compared with nitrogen and helium mixtures. Acute lung injury is characterized by regional heterogeneity of lung resistance and elastance that may lead to regional heterogeneity of expiratory time constants (τE). We hypothesized that increasing airflow resistance by using inhaled sulfur hexafluoride (SF6) would lengthen time constants and decrease their heterogeneity in an experimental model of lung injury when compared with nitrogen or helium mixtures. To overcome the limitations of a single-compartment model, we employed a multisegment model of expiratory gas flow. An experimental model of lung injury was created using intratracheal injection of sodium polyacrylate in anaesthetized and mechanically ventilated female Yorkshire-cross pigs (n = 7). The animals were ventilated with 50% O2 and the remaining 50% as nitrogen (N2), helium (He) or sulfur hexafluoride (SF6). Values for τE decreased with injury and were more variable after injury than before (P < 0.001). Values for τE increased throughout expiration both before and after injury, and the rate of increase in τE was lessened by SF6 (P < 0.001 when compared with N2 both before and after injury). Altering the inhaled gas density did not affect indices of oxygenation, dead space or shunt. The use of SF6 in ventilating gas mixtures lengthens total expiratory time constants before and after lung injury compared with both N2 and He mixtures. Importantly, SF6 mixtures also decrease the difference and variability of τE between fast- and slow-emptying compartments before and after injury when compared with N2 and He mixtures., (© 2015 The Authors. Experimental Physiology © 2015 The Physiological Society.)

Published

2015

17. The pulmonary system during exercise in hypoxia and the cold.

Author

Sheel AW, MacNutt MJ, and Querido JS

Subjects

Adaptation, Physiological physiology, Altitude, Humans, Cold Temperature, Hypoxia physiopathology, Lung physiology, Pulmonary Gas Exchange physiology, Sports physiology

Abstract

The demands for pulmonary O(2) and CO(2) transport in the exercising human are substantial. Fortunately, the regulatory and architectural limits of the pulmonary system meet the requirements of heavy exercise in most individuals. However, in some highly trained athletes the high metabolic demand of intense exercise is in excess of the capacity of the pulmonary system. Environmental considerations, in addition to those imposed by the demands of exercise, provide further physiological challenges that must be met. Winter athletes often encounter high-altitude hypoxia and cold, either transiently during competition or repeatedly during training. In this brief review, we examine the pulmonary system during acute and chronic exercise in hypoxic and cold environmental conditions. Observations from studies conducted in humans are emphasized in order to ask questions about regulation, plasticity and the limits of human physiology. We also highlight new findings and controversial questions that would benefit from additional study.

Published

2010

18. A chilly breeze leads to heavy breathing - facial cooling and the human peripheral chemoreflex.

Author

Sheel AW

Subjects

Body Temperature Regulation physiology, Humans, Cold Temperature, Face innervation, Hypoxia physiopathology, Reflex physiology

Published

2008

19. Effects of enhanced human chemosensitivity on ventilatory responses to exercise.

Author

Foster GE, McKenzie DC, and Sheel AW

Subjects

Atmospheric Pressure, Exercise Test, Humans, Hypoxia blood, Male, Oxygen blood, Oxygen Consumption, Partial Pressure, Respiratory Mechanics physiology, Time Factors, Chemoreceptor Cells physiology, Exercise, Hypoxia physiopathology, Pulmonary Ventilation physiology

Abstract

It is not clear what the effects of different types of intermittent hypoxia have on human exercise ventilation. The purpose of this study was to determine whether short-duration intermittent hypoxia, and the subsequent augmentation of the hypoxic ventilatory response (HVR), would lead to an increase in ventilatory responses during exercise at sea level. It was hypothesized that subjects exposed to short-duration intermittent hypoxia would have a greater increase in the ventilatory response to exercise compared to those exposed to long-duration intermittent hypoxia. Subjects (n = 17, male) were randomly assigned to short-duration intermittent hypoxia (SDIH: 5 min of 12% O2 separated by 5 min of normoxia for 1 h) or long-duration intermittent hypoxia (LDIH: 30 min of 12% O2). Both groups had 10 exposures over a 12 day period. The HVR was measured on days 1 and 12. Maximal oxygen consumption (VO2max) was determined using a ramped cycle exercise test. Maximal exercise data were not different (P > 0.05) between SDIH and LDIH groups or following intermittent hypoxia. Minute ventilation, tidal volume and respiratory frequency were compared at 20, 40, 60, 80 and 100% of VO2max . There was no difference in the ventilatory responses at any intensity of exercise following the intermittent hypoxia period. The HVR was significantly increased following the intermittent hypoxia intervention (P < 0.05) but was not different between SDIH and LDIH (P > 0.05). The relationships between HVR and VO2max were non-significant on day 1 (r = 0.30) and day 12 (r = 0.47; P > 0.05). Our findings point to a lack of functional significance of increasing HVR via intermittent hypoxia on ventilatory responses to exercise at sea level.

Published

2006