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10. Gas Exchange Abnormalities in Mild Bronchitis and Asymptomatic Asthma

Author

Levine G, MacLeod P, Housley E, and Macklem Pt

Subjects
Adult, Male, medicine.medical_specialty, Pathology, Dead space, Physical Exertion, Vital Capacity, Asymptomatic, Oxygen Consumption, Internal medicine, Ventilation-Perfusion Ratio, medicine, Humans, Asthmatic patient, Bronchitis, Lung, Lung Compliance, Tidal volume, Aged, Asthma, business.industry, Respiration, General Medicine, Carbon Dioxide, Middle Aged, medicine.disease, Respiratory Function Tests, Oxygen tension, Oxygen, Pulmonary Alveoli, Spirometry, Breathing, Cardiology, Female, medicine.symptom, business
Abstract

Alveolar arterial tension differences for oxygen, and ratios of physiologic dead space to tidal volume measured at rest, were significantly greater in eight patients with mild bronchitis and seven with asymptomatic asthma as compared to normal controls. Routine pulmonary-function tests, including pulmonary resistance, gave normal or only minimally abnormal results. On exercise, oxygen tension differences became normal in three patients with bronchitis and four with asthma but remained abnormal in the others. Ratios of dead space to tidal volume were normal on exercise in only one bronchitic and three asthmatic patients. Abnormalities of ventilation distribution and gas exchange occur before other abnormalities of lung function become apparent.

Published
1970

12. The Assessment of Diaphragmatic Contractility

Author

Macklem Pt

Subjects
medicine.medical_specialty, business.industry, Respiration, Diaphragm, Diaphragmatic breathing, Contractility, Anesthesiology and Pain Medicine, Text mining, Internal medicine, medicine, Cardiology, Humans, business, Muscle Contraction
Published
1985

14. Bronchial thermoplasty.

Author

Macklem PT, Medford ARL, Agrawal A, Cox G, Thomson NC, and Laviolette M

Published
2007

15. Proceedings from the Montebello Round Table Discussion. Second annual conference on Complexity and Variability discusses research that brings innovation to the bedside.

Author

Seely AJ, Kauffman SA, Bates JH, Macklem PT, Suki B, Marshall JC, Batchinsky AI, Perez-Velazquez JL, Seiver A, McGregor C, Maksym G, Kamath MV, Similowski T, Buchman TG, Letellier C, Filoche M, Frasch MG, Straus C, Glass L, Godin PJ, Morris JA, Sow D, Nenadovic V, Arnold RC, Norris P, and Moorman JR

Subjects
Critical Care, Humans, Quebec, Biomedical Research, Diffusion of Innovation, Point-of-Care Systems
Published
2011
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16. Concomitant ventilatory and circulatory functions of the diaphragm and abdominal muscles.

Author

Aliverti A, Uva B, Laviola M, Bovio D, Lo Mauro A, Tarperi C, Colombo E, Loomas B, Pedotti A, Similowski T, and Macklem PT

Subjects
Adult, Aged, Blood Pressure, Cardiac Output, Female, Femoral Vein physiology, Hepatic Veins physiology, Humans, Male, Plethysmography, Whole Body, Pressure, Regional Blood Flow, Time Factors, Vena Cava, Inferior physiology, Abdominal Muscles physiology, Diaphragm physiology, Hemodynamics, Muscle Contraction, Pulmonary Ventilation, Splanchnic Circulation
Abstract

Expulsive maneuvers (EMs) caused by simultaneous contraction of diaphragm and abdominal muscles shift substantial quantities of blood from the splanchnic circulation to the extremities. This suggests that the diaphragm assisted by abdominal muscles might accomplish ventilation and circulation simultaneously by repeated EMs. We tested this hypothesis in normal subjects by measuring changes (Δ) in body volume (Vb) by whole body plethysmography simultaneously with changes in trunk volume (Vtr) by optoelectronic plethysmography, which measures the same parameters as whole body plethysmography plus the volume of blood shifts (Vbs) between trunk and extremities: Vbs = ΔVtr-ΔVb. We also measured abdominal pressure, pleural pressure, the arterial pressure wave, and cardiac output (Qc). EMs with abdominal pressure ~100 cmH(2)O for 1 s, followed by 2-s relaxations, repeated over 90 s, produced a "stroke volume" from the splanchnic bed of 0.35 ± 0.07 (SD) liter, an output of 6.84 ± 0.75 l/min compared with a resting Qc of 5.59 ± 1.14 l/min. Refilling during relaxation was complete, and the splanchnic bed did not progressively empty. Diastolic pressure increased by 25 mmHg during each EM. Between EMs, Qc increased to 7.09 ± 1.14 l/min due to increased stroke volume and heart rate. The circulatory function of the diaphragm assisted by simultaneous contractions of abdominal muscles with appropriate pressure and duration at 20 min(-1) can produce a circulatory output as great as resting Qc, as well as ventilation. These combined functions of the diaphragm have potential for cardiopulmonary resuscitation. The abdominal circulatory pump can act as an auxiliary heart.

Published
2010
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17. Towards a definition of life.

Author

Macklem PT and Seely A

Subjects
Cell Cycle, Cellular Structures, Chemical Phenomena, Entropy, Humans, Physical Phenomena, Life, Thermodynamics
Abstract

This article offers a new definition of life as a "self-contained, self-regulating, self-organizing, self-reproducing, interconnected, open thermodynamic network of component parts which performs work, existing in a complex regime which combines stability and adaptability in the phase transition between order and chaos, as a plant, animal, fungus, or microbe." Open thermodynamic networks, which create and maintain order and are used by all organisms to perform work, import energy from and export entropy into the environment. Intra- and extracellular interconnected networks also confer order. Although life obeys the laws of physics and chemistry, the design of living organisms is not determined by these laws, but by Darwinian selection of the fittest designs. Over a short range of normalized energy consumption, open thermodynamic systems change from deeply ordered to chaotic, and life is found in this phase transition, where a dynamic balance between stability and adaptability allows for homeokinesis. Organisms and cells move within the phase transition with changes in metabolic rate. Seeds, spores and cryo-preserved tissue are well within the ordered regime, while health probably cannot be maintained with displacements into the chaotic regime. Understanding life in these terms may provide new insights into what constitutes health and lead to new theories of disease.

Published
2010
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18. Therapeutic implications of the pathophysiology of COPD.

Author

Macklem PT

Subjects
Bronchi immunology, Bronchi innervation, Diaphragm innervation, Dyspnea physiopathology, Humans, Pulmonary Alveoli immunology, Respiratory Mechanics physiology, Vital Capacity physiology, Pulmonary Disease, Chronic Obstructive physiopathology, Residual Volume physiology
Abstract

This review examines 18 studies published > or =30 yrs ago. They show that the earliest manifestation of chronic obstructive pulmonary disease (COPD) is an increase in residual volume suggesting that the natural history of COPD is a progressive increase in gas trapping with a decreasing vital capacity (VC). The reduction in VC forces the forced expiratory volume in 1 s to decline with it. This is aggravated by rapid shallow breathing leading to dynamic hyperinflation. The earlier studies show that this is energetically opposite to a minimal work or force pattern and is responsible for dyspnoea and exercise limitation. This information, available for >30 yrs leads to three virtually untested hypotheses: 1) training patients to breathe slowly and deeply transiently during exercise should decrease the work of breathing, dynamic hyperinflation and improve exercise performance; 2) rapid shallow breathing is caused by alveolar and bronchial inflammation that stimulates non-myelinated vagal C-fibre afferents, which are known to cause this breathing pattern; and 3) if so, therapeutic efforts to block these afferents might restore a slow-deep pattern and be beneficial, particularly in COPD exacerbations.

Published
2010
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19. Stephen Hales, an unrecognized giant of medicine.

Author

Macklem PT

Subjects
Animals, Blood Pressure, Hemorrhage history, History, 17th Century, History, 18th Century, Science education, Science history, Biophysical Phenomena, Blood Circulation, Empirical Research, History of Medicine, Physicians history, Respiratory Physiological Phenomena
Published
2010

21. Quantification of trapped gas with CT and 3 He MR imaging in a porcine model of isolated airway obstruction.

Author

Salito C, Aliverti A, Gierada DS, Deslée G, Pierce RA, Macklem PT, and Woods JC

Subjects
Animals, Helium, In Vitro Techniques, Isotopes, Swine, Airway Obstruction diagnostic imaging, Airway Obstruction pathology, Gases, Lung diagnostic imaging, Lung pathology, Magnetic Resonance Imaging, Tomography, X-Ray Computed
Abstract

Purpose: To quantify regional gas trapping in the lung by using computed tomographic (CT)-determined specific gas volume and hyperpolarized helium 3 ((3)He) magnetic resonance (MR) imaging in a porcine model of airway obstruction., Materials and Methods: Four porcine lungs were removed after sacrifice for unrelated cardiac experiments, for which animal studies approval was obtained. Dynamic expiratory thin-section CT and (3)He MR imaging were performed during passive deflation from total lung capacity after obstructions were created with inverted one-way endobronchial exit valves in segmental or lobar bronchi to produce identifiable regions of trapped gas. Changes in specific gas volume were assessed from CT data for defined regions of interest within and outside of obstructed segments and for entire lobes. Helium 3 data were analyzed according to the corresponding regional signal reduction during expiration, compared with the total magnetic moment at each time point., Results: In 4.5 seconds of free collapse, volume decreased by 6% +/- 2 (standard error) and 53% +/- 3, respectively, in trapped-gas lobes and in unobstructed regions (P < .0001). Specific gas volume changed by 6% +/- 2 in areas of trapped gas and decreased by 56% +/- 3 in unobstructed regions, from 3.4 mL/g +/- 0.2 to 1.5 mL/g +/- 0.1 (P < .0001). The (3)He signal intensity decreased by 25% +/- 6 and 71% +/- 3, respectively, in trapped-gas and normal regions (P = .0008). In unobstructed regions, the percentage decreases in specific gas volume and (3)He signal intensity were not statistically different from one another (P = .89)., Conclusion: The results obtained from the model of gas trapping demonstrate that CT-determined specific gas volume and (3)He MR imaging can help identify and quantify the extent of regional trapped gas in explanted porcine lungs., ((c) RSNA, 2009.)

Published
2009
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22. The abdominal circulatory pump.

Author

Aliverti A, Bovio D, Fullin I, Dellacà RL, Lo Mauro A, Pedotti A, and Macklem PT

Subjects
Adult, Blood Pressure physiology, Blood Volume physiology, Exercise physiology, Female, Humans, Male, Plethysmography, Splanchnic Circulation physiology
Abstract

Blood in the splanchnic vasculature can be transferred to the extremities. We quantified such blood shifts in normal subjects by measuring trunk volume by optoelectronic plethysmography, simultaneously with changes in body volume by whole body plethysmography during contractions of the diaphragm and abdominal muscles. Trunk volume changes with blood shifts, but body volume does not so that the blood volume shifted between trunk and extremities (Vbs) is the difference between changes in trunk and body volume. This is so because both trunk and body volume change identically with breathing and gas expansion or compression. During tidal breathing Vbs was 50-75 ml with an ejection fraction of 4-6% and an output of 750-1500 ml/min. Step increases in abdominal pressure resulted in rapid emptying presumably from the liver with a time constant of 0.61+/-0.1SE sec. followed by slower flow from non-hepatic viscera. The filling time constant was 0.57+/-0.09SE sec. Splanchnic emptying shifted up to 650 ml blood. With emptying, the increased hepatic vein flow increases the blood pressure at its entry into the inferior vena cava (IVC) and abolishes the pressure gradient producing flow between the femoral vein and the IVC inducing blood pooling in the legs. The findings are important for exercise because the larger the Vbs the greater the perfusion of locomotor muscles. During asystolic cardiac arrest we calculate that appropriate timing of abdominal compression could produce an output of 6 L/min. so that the abdominal circulatory pump might act as an auxiliary heart.

Published
2009
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23. Airway bypass improves the mechanical properties of explanted emphysematous lungs.

Author

Choong CK, Macklem PT, Pierce JA, Das N, Lutey BA, Martinez CO, and Cooper JD

Subjects
Blood Vessel Prosthesis, Forced Expiratory Volume, Humans, In Vitro Techniques, Lung pathology, Lung Transplantation, Lung Volume Measurements, Pulmonary Ventilation, Stents, Bronchi physiopathology, Bronchi surgery, Lung physiopathology, Lung surgery, Pulmonary Emphysema physiopathology, Pulmonary Emphysema surgery
Abstract

Rationale: By creating artificial communications through bronchial walls into the parenchyma of explanted lungs (airway bypass), we expect to decrease the amount of gas trapped and to increase the rate and volume of air expelled during forced expirations., Objectives: To describe the mechanism by which airway bypass improves the mechanical properties of the emphysematous lung., Methods: Lung compartments and mechanics were measured before and after airway bypass, which was created by placement of three or four stent-supported fenestrations in 10 emphysematous lungs removed at transplantation surgery., Measurements and Main Results: Minimal volume after passive deflation decreased by a mean of 1.54 L (range, 0.7-2.5 L) or 60% (range, 37-86%). Explanted VC increased by 1.30 L or 132% (range, 78-318%). Maximal expiratory flows and volumes increased. Flow resistance decreased., Conclusions: Because these data show that airway bypass improves the mechanics of breathing in severely emphysematous lungs in vitro, there is now strong empirical support that this procedure can improve ventilatory function in patients by reducing gas trapping and flow resistance.

Published
2008
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24. Last Word on Point:Counterpoint: The major limitation to exercise performance in COPD is 1) inadequate energy supply to the respiratory and locomotor muscles, 2) lower limb muscle dysfunction, 3) dynamic hyperinflation.

Author

Aliverti A and Macklem PT

Subjects
Humans, Muscle, Skeletal metabolism, Respiratory Muscles metabolism, Energy Metabolism physiology, Exercise Tolerance physiology, Lower Extremity physiopathology, Muscle, Skeletal physiopathology, Pulmonary Disease, Chronic Obstructive physiopathology, Respiratory Mechanics physiology, Respiratory Muscles physiopathology
Published
2008
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25. The major limitation to exercise performance in COPD is inadequate energy supply to the respiratory and locomotor muscles.

Author

Aliverti A and Macklem PT

Subjects
Humans, Lower Extremity physiology, Oxygen Consumption physiology, Energy Metabolism physiology, Exercise Tolerance physiology, Locomotion physiology, Muscle, Skeletal physiopathology, Pulmonary Disease, Chronic Obstructive physiopathology, Respiratory Mechanics physiology, Respiratory Muscles physiopathology
Published
2008
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26. Dividing the FEV1 into its component parts.

Author

Macklem PT and Irvin CG

Subjects
Asthma physiopathology, Bronchodilator Agents, Forced Expiratory Volume drug effects, Humans, Methacholine Chloride, Vital Capacity drug effects, Vital Capacity physiology, Forced Expiratory Volume physiology
Published
2008
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27. Emergent phenomena and the secrets of life.

Author

Macklem PT

Subjects
Amoeba metabolism, Animals, Comprehension, Extinction, Biological, Humans, Myxomycetes metabolism, Nonlinear Dynamics, Selection, Genetic, Thermodynamics, Adaptation, Physiological, Biological Evolution, Energy Metabolism physiology, Models, Biological, Systems Biology
Published
2008
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28. Chest wall dynamics and muscle recruitment during professional flute playing.

Author

Cossette I, Monaco P, Aliverti A, and Macklem PT

Subjects
Abdominal Muscles physiology, Adaptation, Physiological, Adult, Electromyography, Female, Humans, Male, Muscle, Skeletal physiology, Occupations, Reference Values, Respiratory Sounds physiology, Vital Capacity physiology, Inspiratory Capacity physiology, Music, Respiratory Mechanics physiology, Respiratory Muscles physiology, Thoracic Wall physiology
Abstract

Respiratory parameters and sound were recorded during professional flute playing in order to assess what physiological processes were associated with the control of sound production that results in 'breath support' which in turn is associated with high quality playing. Four standing young professional flautists played flute excerpts with and without breath support. Recordings included optoelectronic plethysmographic measurements of chest wall volume (V(cw)) and its compartments, surface electromyography of the scalene, lateral abdominal, rectus abdominus, parasternal and sternocleidomastoid muscles, mouth pressure, and sound. Flow was estimated from differentiating V(cw) during playing. Results showed that flute support entails antagonistic contraction of non-diaphragmatic inspiratory muscles that tends to hold the rib cage at higher lung volume. This relieves the expiratory muscles from the task of producing the right mouth pressure, especially at the end of the phrases, so they can contribute more to the finer control of mouth pressure modulations required for high quality playing.

Published
2008
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29. At Last! A Realistic Animal Model of Severe Asthma.

Author

Macklem PT

Subjects
Animals, Bronchoconstriction physiology, Bronchoconstrictor Agents pharmacology, Drug Synergism, Hypersensitivity physiopathology, Ovalbumin pharmacology, Polylysine pharmacology, Asthma chemically induced, Asthma physiopathology, Bronchial Hyperreactivity chemically induced, Bronchial Hyperreactivity physiopathology, Disease Models, Animal
Published
2008
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31. Percolation and phase transitions.

Author

Fessler HE and Macklem PT

Subjects
Disease Progression, Humans, Nonlinear Dynamics, Collagen metabolism, Elastin metabolism, Lung Diseases metabolism, Models, Biological
Published
2007
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32. A human model of the pathophysiology of chronic obstructive pulmonary disease.

Author

Aliverti A, Kayser B, and Macklem PT

Subjects
Cardiac Output physiology, Exercise physiology, Humans, Hypercapnia physiopathology, Pulmonary Alveoli physiopathology, Respiratory Muscles physiopathology, Tidal Volume physiology, Pulmonary Disease, Chronic Obstructive physiopathology
Abstract

This short review summarizes a series of studies on the effects of expiratory flow limitation (EFL) at approximately 1 L/s during incremental exercise to maximal workload (Wmax) in normal subjects on exercise performance, respiratory muscle dynamics and control, and CO(2) elimination. Each subject served as his or her own control by performing the same protocol without EFL. Additionally, an index of cardiac output was measured before and after imposing EFL while the subjects exercised at Wmax, Wmax was reduced to 65% of control by severe dyspnoea. EFL forced a decrease in the shortening velocity of expiratory muscles, resulting in increased expiratory pressures which accounted for 66% of the variance in Borg scale ratings of dyspnoea. In spite of an increase in the shortening velocity of inspiratory muscles, inspiratory pressures and power increased, because EFL exercise induced hypercapnia, which increased the chemical drive to breathe. This was in part due to an increased alveolar dead space presumably resulting from a reduction in pulmonary capillary blood volume secondary to the high expiratory pressures. A vicious circle was established in which expiratory muscle pressures induced hypercapnia, which resulted in an even stronger expiratory muscle contraction. The imposition of EFL reduced cardiac output by 10% and decreased arterial O(2) saturation, reducing energy supplies to working locomotor and respiratory muscles. This model reproduces the most important clinical features of COPD, and these arise from ventilatory pump dysfunction rather than from the lung. It also leads to hypotheses that can be tested in patients with COPD.

Published
2007
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33. Transpleural ventilation of explanted human lungs.

Author

Choong CK, Macklem PT, Pierce JA, Lefrak SS, Woods JC, Conradi MS, Yablonskiy DA, Hogg JC, Chino K, and Cooper JD

Subjects
Female, Forced Expiratory Volume physiology, Humans, In Vitro Techniques, Lung Volume Measurements, Male, Pleura, Vital Capacity physiology, Lung physiology, Pulmonary Emphysema physiopathology, Pulmonary Ventilation physiology, Respiration
Abstract

Background: The hypothesis that ventilation of emphysematous lungs would be enhanced by communication with the parenchyma through holes in the pleural surface was tested., Methods: Fresh human lungs were obtained from patients with emphysema undergoing lung transplantation. Control human lungs were obtained from organ donors whose lungs, for technical reasons, were not considered suitable for implantation. Lungs were ventilated through the bronchial tree or transpleurally via a small hole communicating with the underlying parenchyma over which a flanged silicone tube had been cemented to the surface of the lung (spiracle). Measurements included flow-volume-time curves during passive deflation via each pathway; volume of trapped gas recovered from lungs via spiracles when no additional gas was obtainable passively from the airways; and magnetic resonance imaging assessment of spatial distribution of hyperpolarised helium ((3)He) administered through either the airways or spiracles., Results: In emphysematous lungs, passively expelled volumes at 20 s were 94% greater through spiracles than via the airways. Following passive deflation from the airways, an average of 1.07 litres of trapped gas volume was recoverable via spiracles. Regions were ventilated by spiracles that were less well ventilated via bronchi., Conclusions: Because of the extensive collateral ventilation present in emphysematous lungs, direct communication with the lung parenchyma through non-anatomical pathways has the potential to improve the mechanics of breathing and hence ventilation.

Published
2007
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34. Oxygen kinetics and debt during recovery from expiratory flow-limited exercise in healthy humans.

Author

Vogiatzis I, Zakynthinos S, Georgiadou O, Golemati S, Pedotti A, Macklem PT, Roussos C, and Aliverti A

Subjects
Carbon Dioxide metabolism, Cardiac Output, Forced Expiratory Volume, Humans, Hypercapnia metabolism, Hypercapnia physiopathology, Hypoxia metabolism, Hypoxia physiopathology, Kinetics, Male, Models, Biological, Oxygen blood, Pulmonary Disease, Chronic Obstructive physiopathology, Reference Values, Exercise Tolerance, Exhalation, Muscle, Skeletal metabolism, Oxygen metabolism, Oxygen Consumption, Pulmonary Ventilation
Abstract

In healthy subjects expiratory flow limitation (EFL) during exercise can lower O(2) delivery to the working muscles. We hypothesized that if this affects exercise performance it should influence O(2) kinetics at the end of exercise when the O(2) debt is repaid. We performed an incremental exercise test on six healthy males with a Starling resistor in the expiratory line limiting expiratory flow to approximately 1 l s(-1) to determine maximal EFL exercise workload (W (max)). In two more square-wave exercise runs subjects exercised with and without EFL at W (max) for 6 min, while measuring arterial O(2) saturation (% SaO(2)), end-tidal pressure of CO(2) (P (ET)CO(2)) and breath-by-breath O(2) consumption VO2 taking into account changes in O(2) stored in the lungs. Over the last minute of EFL exercise, mean P (ET)CO(2) (54.7 +/- 9.9 mmHg) was significantly higher (P < 0.05) compared to control (41.4 +/- 3.9 mmHg). At the end of EFL exercise %SaO(2) fell significantly by 4 +/- 3%. When exercise stopped, EFL was removed, and we continued to measure VO2. During recovery, there was an immediate step increase in [Formula: see text] so that repayment of EFL O(2) debt started at a higher VO2 than control. Recovery VO2 kinetics after EFL exercise was best characterized by a double-exponential function with fundamental and slow time constants of 27 +/- 11 and 1,020 +/- 305 s, compared to control values of 41 +/- 10 and 1,358 +/- 320 s, respectively. EFL O(2) debt was 52 +/- 22% greater than control (2.19 +/- 0.58 vs. 1.49 +/- 0.38 l). We conclude that EFL exercise increases the O(2) debt and leads to hypoxemia in part due to hypercapnia.

Published
2007
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35. Hyperpolarized 3He diffusion MRI and histology in pulmonary emphysema.

Author

Woods JC, Choong CK, Yablonskiy DA, Bentley J, Wong J, Pierce JA, Cooper JD, Macklem PT, Conradi MS, and Hogg JC

Subjects
Administration, Inhalation, Contrast Media administration & dosage, Humans, In Vitro Techniques, Isotopes administration & dosage, Lung metabolism, Pulmonary Emphysema metabolism, Reproducibility of Results, Sensitivity and Specificity, Diffusion Magnetic Resonance Imaging methods, Helium administration & dosage, Helium chemistry, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Lung pathology, Pulmonary Emphysema pathology
Abstract

Diffusion MRI of hyperpolarized (3)He shows that the apparent diffusion coefficient (ADC) of (3)He gas is highly restricted in the normal lung and becomes nearly unrestricted in severe emphysema. The nature of this restricted diffusion provides information about lung structure; however, no direct comparison with histology in human lungs has been reported. The purpose of this study is to provide information about (3)He gas diffusivity in explanted human lungs, and describe the relationship between (3)He diffusivity and the surface area to lung volume ratio (SA/V) and mean linear intercept (L(m)) measurements--the gold standard for diagnosis of emphysema. Explanted lungs from patients who were undergoing lung transplantation for advanced COPD, and donor lungs that were not used for transplantation were imaged via (3)He diffusion MRI. Histological measurements were made on the same specimens after they were frozen in the position of study. There is an inverse correlation between diffusivity and SA/V (and a positive correlation between diffusivity and L(m)). An important result is that restricted (3)He diffusivity separated normal from emphysematous lung tissue more clearly than the morphometric analyses. This effect may be due to the smaller histologic sampling size compared to the MRI voxel sizes.

Published
2006
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36. Long-range diffusion of hyperpolarized 3He in explanted normal and emphysematous human lungs via magnetization tagging.

Author

Woods JC, Yablonskiy DA, Choong CK, Chino K, Pierce JA, Hogg JC, Bentley J, Cooper JD, Conradi MS, and Macklem PT

Subjects
Emphysema surgery, Humans, In Vitro Techniques, Lung Transplantation, Nitrogen, Pulmonary Alveoli pathology, Emphysema pathology, Helium, Isotopes, Magnetic Resonance Imaging methods
Abstract

Long-range diffusivity of hyperpolarized 3He gas was measured from the decay rate of sinusoidally modulated longitudinal nuclear magnetization in three normal donor and nine severely emphysematous explanted human lungs. This (long-range) diffusivity, which we call Dsec, is measured over seconds and centimeters and is approximately 10 times smaller in healthy lungs (0.022 cm2/s) than the more traditionally measured Dmsec, which is measured over milliseconds and submillimeters. The increased restriction of Dsec reflects the complex, tortuous paths required to navigate long distances through the maze of branching peripheral airways. In emphysematous lungs, Dsec is substantially increased, with some regions showing nearly the unrestricted value of the self-diffusion coefficient (0.88 cm2/s for dilute 3He in air, a 40-fold increase). This suggests the presence of large collateral pathways opened by alveolar destruction that bypass the airways proper. This destruction was confirmed by comparison with histology in seven lungs and by removal of trapped gas via holes in the pleural surface in five lungs.

Published
2005
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38. Influence of expiratory flow-limitation during exercise on systemic oxygen delivery in humans.

Author

Aliverti A, Dellacà RL, Lotti P, Bertini S, Duranti R, Scano G, Heyman J, Lo Mauro A, Pedotti A, and Macklem PT

Subjects
Adult, Blood Pressure physiology, Cardiac Output physiology, Exercise Test, Female, Humans, Lung physiology, Lung Volume Measurements, Male, Pulmonary Gas Exchange physiology, Exercise physiology, Oxygen Consumption physiology, Pulmonary Ventilation physiology
Abstract

To determine the effects of exercise with expiratory flow-limitation (EFL) on systemic O(2) delivery, seven normal subjects performed incremental exercise with and without EFL at approximately 0.8 l s(-1) (imposed by a Starling resistor in the expiratory line) to determine maximal power output under control (W'(max,c)) and EFL (W'(max,e)) conditions. W'(max,e) was 62.5% of W'(max,c), and EFL exercise caused a significant fall in the ventilatory threshold. In a third test, after exercising at W'(max,e) without EFL for 4 min, EFL was imposed; exercise continued for 4 more minutes or until exhaustion. O(2) consumption (V'(O)(2)) was measured breath-by-breath for the last 90 s of control, and for the first 90 s of EFL exercise. Assuming that the arterio-mixed venous O(2) content remained constant immediately after EFL imposition, we used V'(O)(2) as a measure of cardiac output (Q'(c)). Q'(c) was also calculated by the pulse contour method with blood pressure measured continuously by a photo-plethysmographic device. Both sets of data showed a decrease of Q'(c) due to a decrease in stroke volume by 10% (p < 0.001 for V'(O)(2)) with EFL and remained decreased for the full 90 s. Concurrently, arterial O(2) saturation decreased by 5%, abdominal, pleural and alveolar pressures increased, and duty cycle decreased by 43%. We conclude that this combination of events led to a decrease in venous return secondary to high expiratory pressures, and a decreased duty cycle which decreased O(2) delivery to working muscles by approximately 15%.

Published
2005
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39. Complex systems and the technology of variability analysis.

Author

Seely AJ and Macklem PT

Subjects
Data Interpretation, Statistical, Entropy, Fourier Analysis, Heart Rate physiology, Humans, Multiple Organ Failure physiopathology, Critical Illness, Models, Biological, Monitoring, Physiologic methods
Abstract

Characteristic patterns of variation over time, namely rhythms, represent a defining feature of complex systems, one that is synonymous with life. Despite the intrinsic dynamic, interdependent and nonlinear relationships of their parts, complex biological systems exhibit robust systemic stability. Applied to critical care, it is the systemic properties of the host response to a physiological insult that manifest as health or illness and determine outcome in our patients. Variability analysis provides a novel technology with which to evaluate the overall properties of a complex system. This review highlights the means by which we scientifically measure variation, including analyses of overall variation (time domain analysis, frequency distribution, spectral power), frequency contribution (spectral analysis), scale invariant (fractal) behaviour (detrended fluctuation and power law analysis) and regularity (approximate and multiscale entropy). Each technique is presented with a definition, interpretation, clinical application, advantages, limitations and summary of its calculation. The ubiquitous association between altered variability and illness is highlighted, followed by an analysis of how variability analysis may significantly improve prognostication of severity of illness and guide therapeutic intervention in critically ill patients.

Published
2004
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42. Breath-by-breath assessment of alveolar gas stores and exchange.

Author

Aliverti A, Kayser B, and Macklem PT

Subjects
Adult, Bicycling, Exercise physiology, Exhalation, Humans, Lung Volume Measurements, Male, Models, Biological, Oxygen Consumption, Plethysmography, Gases metabolism, Monitoring, Physiologic methods, Pulmonary Alveoli metabolism, Pulmonary Gas Exchange
Abstract

The volume of O(2) exchanged at the mouth during a breath (Vo(2,m)) is equal to that taken up by pulmonary capillaries (Vo(2,A)) only if lung O(2) stores are constant. The latter change if either end-expiratory lung volume (EELV), or alveolar O(2) fraction (Fa(O(2))) change. Measuring this requires breath-by-breath (BbB) measurement of absolute EELV, for which we used optoelectronic plethysmography combined with measurement of O(2) fraction at the mouth to measure Vo(2,A) = Vo(2,m) - (DeltaEELV x Fa(O(2)) + EELV x DeltaFa(O(2))), and divided by respiratory cycle time to obtain BbB O(2) consumption (Vo(2)) in seven healthy men during incremental exercise and recovery. To synchronize O(2) and volume signals, we measured gas transit time from mouthpiece to O(2) meter and compared Vo(2) measured during steady-state exercise by using expired gas collection with the mean BbB measurement over the same time period. In one subject, we adjusted the instrumental response time by 20-ms increments to maximize the agreement between the two Vo(2) measurements. We then applied the same total time delay (transit time plus instrumental delay = 660 ms) to all other subjects. The comparison of pooled data from all subjects revealed r(2) = 0.990, percent error = 0.039 +/- 1.61 SE, and slope = 1.02 +/- 0.015 (SE). During recovery, increases in EELV introduced systematic errors in Vo(2) if measured without taking DeltaEELV x Ca(O(2))+EELV x DeltaFa(O(2)) into account. We conclude that optoelectronic plethysmography can be used to measure BbB Vo(2) accurately when studying BbB gas exchange in conditions when EELV changes, as during on- and off-transients.

Published
2004
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44. Detection of expiratory flow limitation in COPD using the forced oscillation technique.

Author

Dellacà RL, Santus P, Aliverti A, Stevenson N, Centanni S, Macklem PT, Pedotti A, and Calverley PM

Subjects
Aged, Air Pressure, Airway Resistance physiology, Exhalation physiology, Female, Humans, Lung Volume Measurements, Male, Middle Aged, Pulmonary Alveoli physiopathology, Pulmonary Disease, Chronic Obstructive physiopathology, Reference Values, Respiratory Mechanics physiology, Forced Expiratory Flow Rates physiology, Oscillometry methods, Pulmonary Disease, Chronic Obstructive diagnosis
Abstract

Expiratory flow limitation (EFL) during tidal breathing is a major determinant of dynamic hyperinflation and exercise limitation in chronic obstructive pulmonary disease (COPD). Current methods of detecting this are either invasive or unsuited to following changes breath-by-breath. It was hypothesised that tidal flow limitation would substantially reduce the total respiratory system reactance (Xrs) during expiration, and that this reduction could be used to reliably detect if EFL was present. To test this, 5-Hz forced oscillations were applied at the mouth in seven healthy subjects and 15 COPD patients (mean +/- sD forced expiratory volume in one second was 36.8 +/- 11.5% predicted) during quiet breathing. COPD breaths were analysed (n=206) and classified as flow-limited if flow decreased as alveolar pressure increased, indeterminate if flow decreased at constant alveolar pressure, or nonflow-limited. Of these, 85 breaths were flow-limited, 80 were not and 41 were indeterminate. Among other indices, mean inspiratory minus mean expiratory Xrs (deltaXrs) and minimum expiratory Xrs (Xexp,min) identified flow-limited breaths with 100% specificity and sensitivity using a threshold between 2.53-3.12 cmH2O x s x L(-1) (deltaXrs) and -7.38- -6.76 cmH2O x s x L(-1) (Xexp,min) representing 6.0% and 3.9% of the total range of values respectively. No flow-limited breaths were seen in the normal subjects by either method. Within-breath respiratory system reactance provides an accurate, reliable and noninvasive technique to detect expiratory flow limitation in patients with chronic obstructive pulmonary disease.

Published
2004
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46. Effects of rapid saline infusion on lung mechanics and airway responsiveness in humans.

Author

Pellegrino R, Dellaca R, Macklem PT, Aliverti A, Bertini S, Lotti P, Agostoni P, Locatelli A, and Brusasco V

Subjects
Administration, Inhalation, Adult, Airway Obstruction chemically induced, Airway Obstruction physiopathology, Female, Forced Expiratory Volume, Humans, Infusions, Intravenous, Male, Respiratory Function Tests, Severity of Illness Index, Spirometry, Time Factors, Vital Capacity, Lung drug effects, Lung physiology, Methacholine Chloride administration & dosage, Respiratory Physiological Phenomena, Respiratory System drug effects, Sodium Chloride administration & dosage
Abstract

Lung mechanics and airway responsiveness to methacholine (MCh) were studied in seven volunteers before and after a 20-min intravenous infusion of saline. Data were compared with those of a time point-matched control study. The following parameters were measured: 1-s forced expiratory volume, forced vital capacity, flows at 40% of control forced vital capacity on maximal (Vm(40)) and partial (Vp(40)) forced expiratory maneuvers, lung volumes, lung elastic recoil, lung resistance (Rl), dynamic elastance (Edyn), and within-breath resistance of respiratory system (Rrs). Rl and Edyn were measured during tidal breathing before and for 2 min after a deep inhalation and also at different lung volumes above and below functional residual capacity. Rrs was measured at functional residual capacity and at total lung capacity. Before MCh, saline infusion caused significant decrements of forced expiratory volume in 1 s, Vm(40), and Vp(40), but insignificantly affected lung volumes, elastic recoil, Rl, Edyn, and Rrs at any lung volume. Furthermore, saline infusion was associated with an increased response to MCh, which was not associated with significant changes in the ratio of Vm(40) to Vp(40). In conclusion, mild airflow obstruction and enhanced airway responsiveness were observed after saline, but this was not apparently due to altered elastic properties of the lung or inability of the airways to dilate with deep inhalation. It is speculated that it was likely the result of airway wall edema encroaching on the bronchial lumen.

Published
2003
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47. Airway wall remodeling: friend or foe?

Author

McParland BE, Macklem PT, and Pare PD

Subjects
Airway Resistance physiology, Animals, Elasticity, Epithelium physiopathology, Humans, Muscle Contraction physiology, Muscle, Smooth anatomy & histology, Muscle, Smooth physiology, Asthma physiopathology, Bronchi physiopathology, Bronchial Hyperreactivity physiopathology
Abstract

Airway wall remodeling is well documented for asthmatic airways and is believed to result from chronic and/or short-term exposure to inflammatory stimuli. Airway wall remodeling can contribute to airway narrowing as well as to the airway hyperresponsiveness, which is a characteristic abnormality in asthma. However, the potential for airway narrowing could be much worse if it were not for some of the protective effects of remodeling that may help to limit airway narrowing in asthmatic patients. This minireview discusses the evidence for airway wall remodeling and its effects, friend and/or foe, on airway narrowing in asthmatic patients.

Published
2003
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49. Chest wall kinematic determinants of diaphragm length by optoelectronic plethysmography and ultrasonography.

Author

Aliverti A, Ghidoli G, Dellacà RL, Pedotti A, and Macklem PT

Subjects
Adult, Analysis of Variance, Biomechanical Phenomena, Humans, Male, Plethysmography, Regression Analysis, Reproducibility of Results, Ultrasonography, Diaphragm diagnostic imaging, Thoracic Wall physiology
Abstract

To estimate diaphragm fiber length from thoracoabdominal configuration, we measured axial motion of the right-sided area of apposition by ultrasonography and volumes displaced by chest wall compartments [pulmonary, abdominal rib cage, and abdomen (Vab)] by optoelectronic plethysmography in four normal men during quiet breathing and incremental exercise without and with expiratory flow limitation. Points at the cephalic area of apposition border were digitized from echo images and mapped into three-dimensional space, and the axial distance from the xyphoidal transverse plane (D(ap)) was measured simultaneously with the volumes. Linear regression analysis between changes (Delta) in D(ap) and the measured volume changes under all conditions showed that 1) DeltaD(ap) was linearly related more to DeltaVab than to changes in pulmonary and abdominal rib cage volumes; and 2) this was highly repeatable between measures. Multiple stepwise regression analysis showed that DeltaVab accounted for 89-96% of the variability of DeltaD(ap), whereas the rib cage compartments added <1%. We conclude that, under conditions of quiet breathing and exercise, with and without expiratory flow limitation, instantaneous DeltaD(ap) can be estimated from DeltaVab.

Published
2003
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50. Phonospirometry for noninvasive measurement of ventilation: methodology and preliminary results.

Author

Que CL, Kolmaga C, Durand LG, Kelly SM, and Macklem PT

Subjects
Airway Obstruction physiopathology, Asthma physiopathology, Head physiology, Humans, Inhalation, Movement physiology, Posture physiology, Reference Values, Reproducibility of Results, Respiratory Mechanics, Tidal Volume, Trachea physiopathology, Pulmonary Ventilation, Respiration, Respiratory Sounds, Spirometry methods, Trachea physiology
Abstract

We measured tracheal flow from tracheal sounds to estimate tidal volume, minute ventilation (VI), respiratory frequency, mean inspiratory flow (VT/TI), and duty cycle (TI/Ttot). In 11 normal subjects, 3 patients with unstable airway obstruction, and 3 stable asthmatic patients, we measured tracheal sounds and flow twice: first to derive flow-sound relationships and second to obtain flow-volume relationships from the sound signal. The flow-volume relationship was compared with pneumotach-derived volume. When subjects were seated, facing forward and with neck rotation, flexion, and standing, flow-volume relationship was within 15% of pneumotach-derived volume. Error increased with neck extension and while supine. We then measured ventilation without mouthpiece or nose clip from tracheal sounds during quiet breathing for up to 30 min. Normal results +/- SD revealed tidal volume = 0.37 +/- 0.065 liter, respiratory frequency = 19.3 +/- 3.5 breaths/min, VI = 6.9 +/- 1.2 l/min, VT/TI = 0.31 +/- 0.06 l/s, and TI/Ttot = 0.37 +/- 0.04. Unstable airway obstruction had large VI due to increased VT/TI. With the exception of TI/Ttot, variations in ventilatory parameters were closer to log normal than normal distributions and tended to be greater in patients. We conclude that phonospirometry measures ventilation reasonably accurately without mouthpiece, nose clip, or rigid postural constraints.

Published
2002
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