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Atmung

  • Karl Stangl
  • Michael Laule
Conference paper

Zusammenfassung

Bei den meßtechnischen Limitationen von Herzschrittmachern können aus der Gruppe der respiratorischen Parameter derzeit nur die Atemfrequenz und das Atemzugvolumen erfaßt werden.

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Literatur

  1. Adrian ED (1933) Afferent impulses in the vagus and their effect on respiration. J Physiol (Lond.) 79:332Google Scholar
  2. Alt E, Heinz M, Hirgstetter C, Emslander P, Daum S, Blömer H (1987) Control of pacemaker rate by impedance-based respiratory minute ventilation. Chest 92: 247PubMedCrossRefGoogle Scholar
  3. Aquilina M, Liverani L, Giulianini G, Musi P (1988) Data processing of transthoracic impedance signal (TIS) to optimize its relationship with physical activity in respiratory dependent pacemakers. PACE 11:809Google Scholar
  4. Bartels H (1975) Gaswechsel (Atmung) In: Keidel WD (Hrsg) Kurzgefaßtes Lehrbuch der Physiologie. Thieme, StuttgartGoogle Scholar
  5. Bouckaert JJ, Dautrebande L, Heymans C (1931) Sinus caroticus and respiratory reflexes. Influence of CO2, hydrogen ion concentration and anoxaemia. J Physiol (Lond.)71, v–viGoogle Scholar
  6. Breuer J (1868) Die Selbststeuerung der Atmung durch den Nervus Vagus. Sitzber Math Naturw Cl (Wien) 57(2):672Google Scholar
  7. Camm AJ, Garratt CJ (1988) Rate-adaptive pacing guided by minute ventilation. In: Santini M, Pistolese M, Alliegro A (eds) Progress in Clinical Pacing. Excerpta Medica, Amsterdam, Hong Kong, Manila, Princeton, Sydney, Tokyo, p107Google Scholar
  8. Casaburi R, Whipp BJ, Wasserman K (1977) Ventilatory and gas exchange dynamics in response to sinusoidal work. J Appl Physiol 42: 300PubMedGoogle Scholar
  9. Comroe JH (1939) The location and function of the chemoreceptors of the aorta. Am J Physiol 127(1):179Google Scholar
  10. Dejour P (1964) Control in respiration in muscular exercise. In: Fenn WO, Rahn H (eds) Handbook of Physiology. Respiration 1. Washinghton, DC, p631Google Scholar
  11. Eldrigde FL, Milhorn DE, Waldrop TG (1981) Exercise hyperpnea and locomotion: parallel activation from the hypothalamus. Science 211:844CrossRefGoogle Scholar
  12. Fee JA, Schultz K, Fischer S, Abi-Samra F, Batey R, Benge W, Camm J, Kay N, Lau CP, Lin H, Maloney JD, Mond H, Redd R, Sweet RL, Shehane R (1988) Preliminary clinical results of the Meta MV rate responsive pacemaker. PACE 11:810Google Scholar
  13. Funke HD (1975) Ein Herzschrittmacher mit belastungsabhängiger Frequenzregulation. Biomed Technik 20:225CrossRefGoogle Scholar
  14. Galli R, Aquilina M, Pariapiano M, Coli G, Laporta P (1988) A patient simulator for „in vitro“ analysis of respiratory dependent pacemakers. PACE 11:809Google Scholar
  15. Hansen JE (1886) Respiratory abnormalities: exercise evaluation of the dyspnoic patient. In: Leff AR (ed) Cardiopulmonary exercise testing. Grune & Stratton, Orlando, p69Google Scholar
  16. Heymans C, Bouckaert JJ, Dautrebande L (1930). Role reflexogene respiratoire des zones vaso-sensibles cardio-aortique et sino-carotidiennes: Ion hydrogene, CO2, sinus-carotidiens et reflexes respiratoires. CR Soc Biol (Paris) 105:881Google Scholar
  17. Hornbein TF, Sorensen SC, Parks CR (1969). Role of muscle spindles in lower extremities in breathing during bicycle exercise. J Appl Physiol 27:476PubMedGoogle Scholar
  18. Ionescu VL (1980). An „on demand pacemaker“ responsive to respiration rate. PACE 3:375Google Scholar
  19. Koepchen HP (1975). Atmungsregulation. In: Gauer OH, Kramer K, Jung R (Hrsg) Physiologie des Menschen (Bd.6): Atmung. Urban und Schwarzenberg, München, Berlin, WienGoogle Scholar
  20. Lampadius MS (1985). Event-triggered rheographic ventilation sensor for pacemaker rate control. In: Gomez FP (ed) Cardiac Pacing. Electrophysiology. Tachyarrhythmias. Editorial Grouz, Madrid, p817Google Scholar
  21. Lau C, Leigh-Jones M, Kingwell S, Ward D, Camm J (1988a). Comparative evaluation of two respiratory sensing rate responsive pacemakers. Pace 11:487Google Scholar
  22. Lau C, Butrous G, Ward D, Camm J (1988b). A rational assessment of rate responsive pacemakers. experience on six different units. Pace 11:488Google Scholar
  23. Leusen IR (1954). Chemosensitivity of the respiratory center. Influence of CO2 in the cerebral ventricles on respiration. Am J Physiol 176:39PubMedGoogle Scholar
  24. Linnarsson D (1974). Dynamics of pulmonary gas exchange at start and end of exercise. Acta Physiol Scand 415(Suppl):1Google Scholar
  25. Mitchell RA, Loeschke HH, Severinghaus JW, Richardson BW, Massion WH (1963). Regions of respiratory chemosensitivity on the surface of the medulla. Ann NY Acad Sci 109:661CrossRefGoogle Scholar
  26. Pioger G, Darwiche H, Vai F, Plicci G (1988). A clinical evaluation of accuracy of respiratory rate detection in multibiorate MB1 pacemaker. PACE 11:809Google Scholar
  27. Pitts RF, Magoun HW, Ranson SW (1939). Localization of the medullary respiratory centers in the cat. Am J Physiol 126:673Google Scholar
  28. Plicci G, Aquilina N, Rognoni G, Capucci A (1988). Bipolar and tripolar electrode configurations for an intravascular respiratory impedance measurement. PACE 11:809Google Scholar
  29. Rossi P, Plicchi G, Canducci G, Rognoni G, Aina F (1983). Respiratory rate as a determinant of optimal pacing rate. PACE 6 (Part II):502PubMedCrossRefGoogle Scholar
  30. Rossi P, Aina F, Rognoni G, Occhetta E, Plicchi G, Prando MD (1984). Increasing cardiac rate by tracking the respiratory rate. PACE 7 (Part II): 1246PubMedCrossRefGoogle Scholar
  31. Rossi P, Rognoni G, Occhetta E, Aina F, Prando MD, Plicchi G, Minella H (1985). Respiration — dependent ventricular pacing compared with fixed ventricular and atrial-ventricular synchronous pacing: aerobic and hemodynamic variables. JACC 6:646PubMedGoogle Scholar
  32. Rossi P, Prando MD, Magnani A, Aina F, Rognoni G, Occhetta E (1988). Physiological sensitivity of respiratory-dependent cardiac pacing: four year follow up. PACE 11:1267PubMedCrossRefGoogle Scholar
  33. Simmons T, Maloney J, Abi-Samra, H Valenta H, Napholtz T, Castle L, Morant V (1986). Exercise — responsive intravascular impedance changes as a rate controller for cardiac pacing. PACE 9:285Google Scholar
  34. Thews G (1985). Lungenatmung. In: Schmidt RF, Thews G. (Hrsg) Physiologie des Menschen. Springer, Berlin Heidelberg New York Tokyo, S 500.Google Scholar
  35. Tibes U (1977). Reflex inputs to the cardiovascular and respiratory centers from dynamically working canine muscles. Circ Res 41:173Google Scholar
  36. Wasserman K, Whipp BJ, Castagna J (1974). Cardiodynamic hyperpnea: hyperpnea secondary to cardiac output increase. J Appl Physiol 36:457PubMedGoogle Scholar
  37. Wasserman K, Whipp BJ (1975). Exercise physiology in health and disease. Am Rev Resp Dis 112:219PubMedGoogle Scholar
  38. Weissman ML, Wasserman K, Huntsman DJ, Whipp BJ (1979). Ventilation and gas exchange during phasic hindlimb exercise in the dog. J Appl Physiol 46:878PubMedGoogle Scholar
  39. Whipp BJ, Wasserman K (1980). Carotid bodies and ventilatory control dynamics in man. Fed Proc 39:2628Google Scholar
  40. Whipp BJ (1981). The control of exercise hyperpnea. In: Hornbein H (ed)The regulation of breathing. Dekker, New York, p1069Google Scholar
  41. Whipp BJ, Ward SA, Lamarra N, Davis JA, Wasserman K (1982). Parameters of ventilatory and gas exchange dynamics during exercise. J Appl Physiol 52:1506PubMedGoogle Scholar
  42. Whipp BJ (1986a). Exercise bioenergetics and gas exchange. In: Leff AR (ed) Cardiopulmonary exercise testing. Grune & Stratton, Orlando, p1Google Scholar
  43. Whipp BJ, Ward SA (1986b). The normal respiratory response in exercise. In: Leff AR (ed) Cardiopulmonary exercise testing. Grune & Stratton, Orlando, p45Google Scholar
  44. Young IH, Woolcock AJ (1978). Changes in arterial blood gas tensions during unsteady-state exercise. J Appl Physiol: Respirat Environ Exercise Physiol 44(1):93Google Scholar

Copyright information

© Dr. Dietrich Steinkopff Verlag, GmbH & Co. KG, Darmstadt 1990

Authors and Affiliations

  • Karl Stangl
  • Michael Laule

There are no affiliations available

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