Zusammenfassung
Durch den Volumsmangel im Rahmen des hypovolämisch-traumatischen Schocks im Polytrauma kommt es zu einem intravaskulären und auch interstitiellen Flüssigkeitsverlust und somit zu einer Minderperfusion von lebenswichtigen und auch untergeordneten System en (z. B. quergestreifte Muskulatur), die zu morphologischen und vor allem funktionellen Veränderungen dieser Organe führt. Als Folge dieser Veränderungen kommt es zu dem pathologischen Zustand des „Organs im Schock“.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
Literatur
Bond RF, Green HD (1983) Peripheral circulation. In: Altura BM, Lefer AM, Schumer W (eds) Handbook of shock and trauma, vol 1. Basic Science, Raven Press, New York, pp 29–49
Border JR, Hassett JM (1987) Multiple systems organ failure: History, pathophysiology, prevention, and support (In press)
Chen RYZ, Fan FC, Schuessler GB, Simchon S, Kim S, Chien S (1984) Regional cerebral blood flow and oxygen consumption of the canine brain during hemorrhagic hypotension. Stroke 15: 343–350
Dempsey PJ, McCallum ZT, Kent KM, Cooper T (1971) Direct myocardial effects of angiotensin II. Am J Physiol 220: 477–481
Downing SE (1983) The heart in shock. In: Altura BM, Lefer AM, Schumer W (eds) Handbook of shock and trauma, Vol 1. Raven Press, New York, pp 5–28
Edwards WS, Siegel A, Bing RJ (1954) Studies on myocardial metabolism. III. Coronary blood flow, myocardial oxygen consumption, and carbohydrate metabolism in experimental hemorrhagic shock. J Clin Invest 33: 1646–1661
Ertl G, Neubauer S, Valldorf T, Kochsiek K (1985) Deterioration of metabolic coronary regulation in hemorrhagic shock. Role of hypoxia and the reninangiotensin system. Res Exp Med 185: 429–443
Euler J, Gerstenbrand F, Krenn J, Lehfuss H (1972) Frühversorgung von Extremitätenfrakturen bei akuter traumatischer Hirnstammschädigung. Mschr Unfallheilk 75: 45–54
Granger DN, Rutili G, McCord JM (1981) Superoxide radicals in feline intestinal ischemia. Gastroenterology 81: 22–29
Green HD, Bond RF, Rapela CE, Schmid HE, Manley E, Farrar DJ (1980) Competition between intrinsic and extrinsic controls of resistance vessels of major vascular beds during hemorrhagic hypotension and shock. In: Lefer AM, Saba TM, Mela LM (eds) Advances in shock research. Alan R. Liss, New York, pp 77–104
Hackel DB, Martin AM, Spach MS, Sieker HO (2964) Hemorrhagic shock in dogs. Arch Pathol Lab Med 77: 575–581
Haglund U (1973) The small intestine in hypotension and hemorrhage. An experimental cardiovascular study in the cat. Acta Physiol Scand Suppl 387
Haglund U, Hulten L, Lundgren O, Ahren C (1985) Mucosal lesions in the human small intestine in shock. Gut 16: 979–984
Hallström S, Vogi C, Krösl P, Redl H, Schlag G (1987) Studies on low molecular weight inotropic plasma substances in prolonged hypovolemic traumatic shock. In: Schlag G, Redl H (eds) Progress in clinical and biological research, vol 236: First Vienna Shock Forum, Part A: Pathophysiological role of mediators and mediator inhibitors in shock. Alan R. Liss, New York, pp 591–597
Heddle RJ, LaBrooy JT, Shearman DJC (1982) Escherichia coli antibody-secreting cells in the human intestine. Clin Exp Immunol 48: 469–476
Heideman M (1985) The role of complement in trauma. Acta Chir Scand Suppl 522: 233–244
Heideman M, Hugli TE (1984) Anaphylatoxin generation in multisystem organ failure. J Trauma 24: 1038–1043
Heimbach DM, Fisher WD, Hutton I, McArdle CS, Ledingham IMcA (1973) Myocardial blood flow and metabolism during and after hemorrhagic shock in the dog. Surg Gynecol Obstet 138: 243–252
Hintze TH, Vatner SF (1982) Cardiac dynamics during hemorrhage. Relative unimportance of adrenergic inotropic responses. Circ Res 50: 705–713
Kauffman GL jr, D’Alecy LG (1977) Redistribution of canine spanchnic blood flow following normotensive hemorrhage. J Surg Res 22: 580–584
Lee JC, Downing SE (1976) Myocardial oxygen availability and cardiac failure in hemorrhagic shock. Am Heart J 92: 201–209
Lefer AM, Martin J (1970) Relationship of plasma peptides to the myocardial depressant factor in hemorrhagic shock in cats. Circ Res 26: 59–69
Lundgaard-Hansen P (1966). Oxygen supply and anaerobic metabolism of the heart in experimental hemorrhagic shock. Ann Surg 163: 10–20
McNeil JR, Stark RD, Greenway CV (1970) Intestinal vasoconstriction after hemorrhage: role of vasopressin and angiotensin. Am J Physiol 219: 1342–1345
Meakins JL, Mashall JC (1986) Multiple-organ-failure syndrome. The gastrointestinal tract: the “motor” of MOF. Arch Surg 121: 196–208
Rapela CE, Green DH (1964) Autoregulation of canine cerebral blood flow. Cric Res 15 (Suppl 1): 1205–1211
Ratliff NB, Hackel DB, Mikat E (1969) Myocardial carbohydrate metabolism and lesions in hemorrhagic shock. Arch Pathol 88: 470–473
Redl H, Hammerschmidt DE, Schlag G (1983) Augmentation by platelets of granulocyte aggregation in response to chemotaxines: studies utilizing an improved cell preparation technique. Blood 61: 125–131
Robinson JWL, Antonioli JA, Mirkovitch V (1966) The intestinal response to ischemia. Arch Pharmakol Exp Path 225: 178–191
Sarnoff SJ, Case RB, Waithe PE, Isaacs JP (1954) Insufficient coronary flow and myocardial failure as a complicating factor in late hemorrhagic shock. Am J Physiol 176: 439–444
Schlag G, Redl H (1986) Oxygen radicals in hypovolemic-traumatic shock. In: Novelli GP, Ursini F (eds) Oxygen free radicals in shock. International Workshop Florence 1985. Karger, Basel, pp 94–108
Schlag G, Voigt WH, Schnells G, Glatzl A (1977) Vergleichende Untersuchungen der Ultrastruktur von menschlicher Lunge und Skelettmuskulatur im Schock. II. Anaesthesist 26: 612–622
Schoenberg MH, Younes M, Muhl E, Haglund U, Sellin D, Schildberg FW (1983) Free radical involvement in ischemic damage of the small intestine. In: Greenwald RA, Cohen G (eds) Oxy radicals and their scavenger systems, vol 2. Elsevier, New York, p 154
Shoemaker WC, Szanto PB, Andersen D (1965) Hepatic hemodynamic and morphologic changes in shock. Arch Pathol 80: 76–83
Slater G, Vladeck Be, Bassin R, Brown RS, Shoemaker WC (1975) Sequential changes in cerebral blood flow and distribution of flow within the brain during hemorrhagic shock. Ann Surg 181: 1–4
Svanvik J (1973) Mucosal hemodynamics in the small intestine of the cat during regional sympathetic vasoconstrictor activation. Acta Physiol Scand 89: 19–22
Varga T, Reffy A, Vandor E (1980) Myocardial lesions in hemorrhagic hypotension. Z Rechtsmed 84: 99–112
Wangensteen SL, Ramey WG, Ferguson WW, Starling JG (1973) Plasma myocardial depressant activity (shock factor) identified as salt in the cat papillary muscle bioassay system. J Trauma 13: 181–194
Wiklund L, Grevsten S, Nilsson F, Norlen BJ, Rimsten A (1976) Non-occlusive enteric gangrene associated with severe upper gastrointestinal bleeding. Acta Chir Scand 142: 593–597
Wright R (1982) Immunology of the gastrointestinal tract and liver. Practitioner 226: 2027–2029
Younes M, Schoenberg MH, Jung H, Fredholm BB, Haglund U, Schildberg FW (1984) Oxidative tissue damage following regional intestinal ischemia and reperfusion in the cat. Res Exp Med 184: 259–264
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 1988 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Schlag, G., Redl, H. (1988). Der traumatische Schock: Antwort auf Hypovolämie und Gewebstrauma. In: Peter, K., Groh, J. (eds) ZAK München 1987. Anaesthesiologie und Intensivmedizin / Anaesthesiology and Intensive Care Medicine, vol 205. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-73785-5_11
Download citation
DOI: https://doi.org/10.1007/978-3-642-73785-5_11
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-19385-2
Online ISBN: 978-3-642-73785-5
eBook Packages: Springer Book Archive