Abstract
In treating a patient presenting respiratory functional impairment, the physician is left with the task of running tests to determine whether there is a mechanical component to the illness. At this point he must be qualified to extract the desired information from a given measurement. Although not difficult to accomplish, the precise interpretation of the results demands awareness of exact methodological and theoretical concepts.
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References
Fry DL (1960) Physiologic recording by modern instruments with particular reference to pressure recording. Physiol Rev 40: 753–788
Butler JP, Leith DE, Jackson AC (1986) Principles of measurement: applications to pressure, volume, and flow. In: Macklem PT, Mead J (eds) Handbook of physiology. The respiratory system. Mechanics of breathing. American Physiological Society, Bethesda, sect 3, vol III, pp 15–33
Behrakis PK, Higgs BD, Baydur A et al (1983) Respiratory mechanics during halothane anesthesia and anesthesia-paralysis in humans. J Appl Physiol 55: 1085–1092
Rocco PRM, Zin WA (1985) Modelling the mechanical effects of tracheal tubes on normal subjects. Eur Respir J 8: 121–126
Beauchamp K, Yuen C (1979) Digital methods for signal analysis. George Allen & Unwin, London
Milic-Emili J, Mead J, Turner JM et al (1964) Improved technique for estimating pleural pressure from esophageal balloons. J Appl Physiol 19: 207–211
Baydur A, Behrakis PK, Zin WA et al (1982) A simple method for assessing the validity of the esophageal balloon technique. Am Rev Respir Dis 126: 788–791
Cook CD, Sutherland JM, Segal S et al (1957) Studies of respiratory physiology in the newborn infant: III. Measurements of mechanics of respiration. J Clin Invest 36: 440–448
Zin WA, Milic-Emili J (1997) Esophageal pressure measurement. In: Tobin MJ (ed) Principles and practice of intensive care monitoring. McGraw-Hill, New York, pp 545–552
Otis AB, Fenn WO, Rahn H (1950) The mechanics of breathing in man. J Appl Physiol 2: 592–607
Sharp JT, Henry JP, Sweany SK et al (1964) Total respiratory inertance and its gas and tissue components in normal and obese men. J Appl Physiol 43: 503–509
Hantos Z, Daróczy B, Klebniczki J et al (1982) Parameter estimation of transpulmonary mechanics by a nonlinear inertive model. J Appl Physiol 52: 955–963
Bates JHT, Shardonofsky F, Stewart DE (1989) The low-frequency dependence of respiratory system resistance and elastance in normal dogs. Respir Physiol 78: 369–382
Mead J, Whittenberger JL (1953) Physical properties of human lungs measured during spontaneous respiration. J Appl Physiol 5: 779–796
Zin WA, Pengelly LD, Milic-Emili J (1982) Single-breath method for measurement of respiratory mechanics in anesthetized animals. J Appl Physiol 52: 1266–1271
Hughes R, May AJ, Widdicombe JG (1959) Stress relaxation in rabbits’ lungs. J Physiol (Lond) 146: 85–97
Don HF, Robson JG (1965) The mechanics of the respiratory system during anesthesia. Anesthesiol 26: 168–178
Bates JHT, Rossi A, Milic-Emili J (1985) Analysis of the behavior of the respiratory system with constant inspiratory flow. J Appl Physiol 58: 1840–1848
Barnas GM, Yoshino K, Loring SH et al (1987) Impedance and relative displacements of relaxed chest wall up to 4 Hz. J Appl Physiol 62: 71–81
Brusasco V, Warner DO, Beck KC et al (1989) Partitioning of pulmonary resistance in dogs: effects of tidal volume and frequency. J Appl Physiol 66: 1190–1197
Hantos Z, Daróczy B, Suki B et al (1986) Forced oscillatory impedance of the respiratory system at low frequencies. J Appl Physiol 60: 123–132
Otis AB, McKerrow CB, Bartlett RA et al (1956) Mechanical factors in the distribution of pulmonary ventilation. J Appl Physiol 8: 427–443
Bates JHT, Baconnier P, Milic-Emili J (1988) A theoretical analysis of interrupter technique for measuring respiratory mechanics. J Appl Physiol 64: 2204–2214
Mead J (1969) Contribution of compliance of airways to frequency-dependent behavior of lungs. J Appl Physiol 26: 670–673
Eyles JG, Pimmel RL (1981) Estimating respiratory mechanical parameters in parallel compartment models. IEEE Trans Biomed Eng 28: 313–317
Peslin R (1986) Methods for measuring total respiratory impedance by forced oscillations. Bull Eur Physiopathol Respir 22: 621–631
Michaelson ED, Grassman ED, Peters WR (1975) Pulmonary mechanics by spectral analysis of forced random noise. J Clin Invest 56: 1210–1230
Lorino AM, Lorino H, Harf A (1994) A synthesis of the Otis, Mead, and Mount mechanical respiratory models. Respir Physiol 97: 123–133
Mount LE (1955) The ventilation flow-resistance and compliance of rat lungs. J Physiol (Lond) 127: 157–167
Bates JHT, Brown KA, Kochi T (1989) Respiratory mechanics in the normal dog determined by expiratory flow interruption. J Appl Physiol 67: 2276–2285
Bates JHT, Ludwig MS, Sly PD et al (1988) Interrupter resistance elucidated by alveolar pressure measurements in open-chest normal dogs. J Appl Physiol 65: 408–414
Saldiva PHN, Zin WA, Santos RLB et al (1992) Alveolar pressure measurement in open-chest rats. J Appl Physiol 72: 302–306
Kochi T, Okubo S, Zin WA et al (1988) Flow and volume dependence of pulmonary mechanics in anesthetized cats. J Appl Physiol 64: 441–450
Similovski T, Levy P, Corbeil C et al (1989) Viscoelastic behavior of lung and chest wall in dogs determined by flow interruption. J Appl Physiol 67: 2219–2229
D’ Angelo E, Calderini E, Torri G et al (1989) Respiratory mechanics in anesthetized-paralyzed humans: effects of flow, volume, and time. J Appl Physiol 67: 2556–2564
Similowski T, Bates JHT (1991) Two-compartment modelling of respiratory system mechanics at low frequencies: gas redistribution of tissue rheology? Eur Respir J 4: 353–358
Navajas D, Farré R, Cannet J et al (1990) Respiratory input impedance in anesthetized paralyzed patients. J Appl Physiol 69: 1372–1379
Shardonofsky F, Sato J, Bates JHT (1990) Quasi-static pressure-volume hysteresis in the canine respiratory system in vivo. J Appl Physiol 68: 2230–2236
Hildebrandt J (1969) Dynamic properties of air-filled excised cat lung determined by liquid plethysmography. J Appl Physiol 27: 246–250
Hildebrandt J (1969) Comparison of mathematical models for cat lung and viscoelastic balloon derived by Laplace transform methods from pressure-volume data. Bull Math Biophys 31: 651–667
Hildebrandt J (1970) Pressure-volume data of cat lung interpreted by a plastoelastic, linear viscoelastic model. J Appl Physiol 28: 365–372
Rohrer F (1915) Der Strömungswiderstand in den menschlichen Atemwegen and der Einfluss der unregelmässigen Verzweigung des Bronchialsystems auf den Atmungsverlauf in verschiedenen Lungenbezirken. Arch Ges Physiol 162: 225–300
Suki B, Bates JHT (1991) A nonlinear viscoelastic model of lung tissue mechanics. J Appl Physiol 71: 826–833
Fredberg JJ, Stamenovic D (1989) On the imperfect elasticity of lung tissue. J Appl Physiol 67: 2408–2419
Hantos Z, Daróczy B, Suki B et al (1992) Input impedance and peripheral inhomogeneity of dog lungs. J Appl Physiol 72: 168–178
Lutchen KR, Suki B, Zhang Q et al (1994) Airway and tissue mechanics during physiological breathing and bronchoconstriction in dogs. J Appl Physiol 77: 373–385
Rotger M, Peslin R, Navajas D et al (1995) Lung and respiratory impedance at low frequency during mechanical ventilation in rabbits. J Appl Physiol 78: 2153–2160
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Zin, W.A. (2000). Principles of Laboratory Research on Respiratory Mechanics. In: Gullo, A. (eds) Anesthesia, Pain, Intensive Care and Emergency Medicine — A.P.I.C.E.. Springer, Milano. https://doi.org/10.1007/978-88-470-2286-7_1
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DOI: https://doi.org/10.1007/978-88-470-2286-7_1
Publisher Name: Springer, Milano
Print ISBN: 978-88-470-0095-7
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