PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników

Czasopismo

2001 | 60 | 4 |

Tytuł artykułu

General anaesthesia in rats undergoing experiments on the central nervous systems

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
The rat is one of the species most commonly used in laboratory practice. Numerous publications concerning various aspects of morphology and physiology are based on the results obtained in this species. It make these results comparable and under some precautions enables to transpose into the relationships observed in humans. Each experimental project must obtain the permission of the Local Ethical Committee, as well as comply with the regulations of the European Communities Council, outlined in the “European Convention for the protection of vertebrate animals used for experimental and other scientific purposes”. Adequate pre-operative care can eliminate or reduce the incidence of many complications, which may occur during anaesthesia. General anaesthesia in experimental practice can be achieved using a variety of drugs and ways of administration, among others inhalational or intravenous. The side effects of anaesthetic agents can be reduced in this way. Knowledge of the effect of anaesthetics on the cerebral circulation, metabolism and intracranial pressure in both normal and pathological conditions is crucial for neurobiological purposes. Many anaesthetic agents depress respiration, which can result in hypoxia, hypercapnia and acidosis. To maintain blood carbon dioxide and oxygen concentration in the physiological range, it is necessary to apply tracheal intubation and artificial ventilation. However, even when using sophisticated equipment, the role of basic clinical observation, such as the colour of the blood shed in the operation field, breathing depth and frequency, cannot be overestimated. The importance of monitoring mean arterial blood pressure and intracranial pressure in experiments on the central nervous system is fundamental. Special attention should be paid to controlling the temperature and monitoring the fluid balance. Appropriate postoperative care can have a decisive influence on the final results of the research.

Słowa kluczowe

Wydawca

-

Czasopismo

Rocznik

Tom

60

Numer

4

Opis fizyczny

p.235-242,fig.,ref.

Twórcy

autor
  • Medical University of Gdansk, Debinki 7, 80-211 Gdansk, Poland
autor
autor

Bibliografia

  • 1. Atumbabic M, Peeling J, Del Bigio MR (1998) Intracerebral hemorrhage in the rat: effects of hematoma aspiration. Stroke, 29: 1917–1923.
  • 2. Blobner M, Kochs E, Fink H, Mayer B, Veihelmann A, Brill T, Stadler J (1999) Pharmacokinetics and pharmacodynamics of vecuronium in rats with systemic inflammatory response syndrome: treatment with NG-monomethyl-L-arginine. Anesthesiology, 91(4): 999–1005.
  • 3. Bonner JT, Hall JR (1985) Respiratory intensive care of the adult surgical patient. The C V Mosby Company St Louis, Toronto, Princeton.
  • 4. Brammer A, West CD, Allen SL (1993) A comparison of propofol with other injectable anaesthetics in a rat model for measuring cardiovascular parameters. Lab Anim, 27: 250–257.
  • 5. Brylińska J, Kwiatkowska J (1996) Zwierzęta laboratoryjne, metody hodowli i doświadczeń. Universitas, Kraków.
  • 6. Carlsson C, Hagerdal M, Siesjö BK (1976) The effect of nitrous oxide on oxygen consumption and blood flow in the cerebral cortex of the rat. Acta Anaesthesiol Scand, 20: 91–95.
  • 7. Cavazzuti M, Porro CA, Biral GP (1987) Ketamine effects on local cerebral blood flow and metabolism in the rat. J Cereb Blood Flow Metab, 7: 806–811.
  • 8. Chambers IR, Mendelow AD, Sinar EJ (1990) A clinical evaluation of the Camino subdural screw and ventricular monitoring kits. Neurosurgery, 26: 421–423.
  • 9. Cockshott ID, Douglas EJ, Plummer GF, Simons PJ (1992) The pharmacokinetics of propofol in laboratory animals. Xenobiotica, 22: 369–375.
  • 10. Coleman AJ (1984) Inhalational anesthetic agents. In: Wylie WD, Churchill-Davidson HC (eds.). A practice of anesthesia. Year Book Medical Publisher Inc. Chicago.
  • 11. Costa DL, Lehmann JR, Harold WM, Drew RT (1986) Transcoral tracheal intubation of rodents using a fiberoptic laryngoscope. Lab Anim Sci, 36: 329–332
  • 12. Countard M, Huang W, Osborne-Pellegrin M (2000) Heritability of intracerebral hemorrhagic lesions and cerebral aneurysms in the rat. Stroke, 31: 2678–2683.
  • 13. Crutchfield JS, Narayan RK, Robertson CS (1990) Evaluation of a fiberoptic intracranial pressure monitor. J Neurosurg, 72: 482–487.
  • 14. Dahlgren N, Ingvar M, Yokoyama H (1981) Influence of nitrous oxide on local cerebral blood flow in awake, minimally restrained rats. J Cereb Blood Flow Metab, 1: 211–218.
  • 15. Decker MJ, Conrad KP, Strobl KP (1989) Noninvasive oximetry in the rat. Bio Instru Tech, May–June: 222–228.
  • 16. Feldman SA (1984) Clinical use of neuromuscular blocking drugs and reversal agents. In: Wylie WD, Churchill-Davidson HC (eds.). A practice of anesthesia. Year Book Medical Publisher Inc. Chicago.
  • 17. Flecknell P (1996) Laboratory animal anaesthesia. Academic Press, London.
  • 18. Glen JB (1980) Animals studies of the anesthetic activity of ICI 35 868. Br J Anaesth, 52: 731–741.
  • 19. Green CJ (1975) Neuroleptoanalgesic drugs combination in the anaesthetic management of small laboratory animals. Lab Anim, 9: 161–178.
  • 20. Green, CJ, Knight I, Precious S, Simpkin S (1981) Ketamine alone and combined with diazepam or xylazine in laboratory animals: a 10-year experience. Lab Anim, 15: 163–170.
  • 21. Greene SA, Thurmon JC (1988) Xylazine — a review of its pharmacology and use in veterinary medicine. J Vet Pharma Therap, 11: 285–313.
  • 22. Gwynne BJ, Wallace JA (1982) A modified anaesthetic induction chamber for rats. Lab Anim, 163–165
  • 23. Han WH, Bellin SI, Dellman HD, Habil V, Hanson CE (1986) Xylazine-ketamine-induced anaesthesia in rats and its antagonism by yohimbine. J Am Vet Med Assoc, 189: 1040–1043.
  • 24. Hu C, Flecknell PA, Liles JH (1992) Fentanyl and medetomidine anaesthesia in the rat and its reversal using atipamazole and either nalbuphine or butorphanol. Lab Anim, 26: 15–22.
  • 25. Karwacki Z, Kowiański P, Moryś J, Dziewiątkowski J, Kaczmarek E, Suchorzewska J (2001) The effect of sevoflurane on intracranial pressure and cardiovascular function in rabbits with experimental intracerebral haematoma. Med Sci Monit, 7(2): 212–217.
  • 26. Karwacki Z, Kowiański P, Dziewiątkowski J, Moryś J, Suchorzewska J (1999) Effect of sevoflurane on intracranial pressure and systemic circulation in rabbit. Med Sci Monit, 5(2): 181–185.
  • 27. Kashimoto S, Furuya A, Nonaka A, Oguchi T, Koshimizu M, Kumazawa T (1997) The minimum alveolar concentration of sevoflurane in rats. Eur J Anaesthesiol, 14(4): 359–361.
  • 28. Levy WJ (1994) Neurophysiologic brain monitoring: Electroencephalography In: Cottrell JE, Smith DS (eds.). Anesthesia and Neurosurgery Mosby-Year Book, Inc. St. Louis, Baltimore, Boston, Chicago, London, Madrid, Philadelphia, Sydney, Toronto.
  • 29. Linton RAF (1984) Pulmonary gas exchange and acidbase status. In: Wylie WD, Churchill-Davidson HC (eds.). A practice of anesthesia. Year Book Medical Publisher Inc. St. Louis, Baltimore, Boston, Chicago, London, Madrid, Philadelphia, Sydney, Toronto.
  • 30. Mazze RI, Rice SA, Baden JM (1985) Halothane, Isoflurane, and Enflurane MAC in pregnant and nonpregnant female and male mice and rats. Anaesthesiology, 62: 339–341.
  • 31. McPherson RW (1994) Neurophysiologic brain monitoring: Evoked Potentials In: Cottrell JE, Smith DS (eds.). Anesthesia and Neurosurgery. Mosby-Year Book, Inc. St. Louis, Baltimore, Boston, Chicago, London, Madrid, Philadelphia, Sydney, Toronto.
  • 32. McPherson RW, Traystman RJ (1984) Fentanyl and cerebral vascular responsivity in dogs. Anesthesiology, 60: 180–186.
  • 33. Michenfelder ID (1974) The interdependency of cerebral functional and metabolic effects following massive doses of thiopental in the dog. Anesthesiology, 41: 231–236.
  • 34. Michenfelder JD, Theye RA (1971) Effects of fentanyl, droperidol and innovar on canine cerebral metabolism and blood flow. Br J Anaesth, 43: 630–636.
  • 35. Miyauchi Y, Sakabe T, Maekawa T (1985) Responses of EEG, cerebral oxygen consumption and blood flow to peripheral nerve stimulation during thiopentone anaesthesia in the dog. Can Anaesth Soc J, 32: 491–498.
  • 36. Moss E (1991) Total intravenous anaesthesia and sedation for neurosurgery. In: Kay B (ed.). Total intravenous anaesthesia. Elsevier Amsterdam, New York Oxford.
  • 37. Nehls DG, Todd MM, Spetzler RE (1983) A comparison of the cerebral protective effects of isoflurane and barbiturates during temporary focal ischemia in primates. Anesthesiology, 59: 23–28.
  • 38. Newberg LA, Michenfelder ID (1983) Cerebral protection by isoflurane during hypoxemia or ischemia. Anaesthesiology, 59: 29–35.
  • 39. Newberg LA, Milde JH, Michenfelder ID (1984) Systemic and cerebral effects of isoflurane-induced hypotension in dogs. Anesthesiology, 60: 541–546.
  • 40. Newberg LA, Milde JH, Michenfelder ID (1987) The cerebral metabolic effects of isoflurane at and above concentrations that suppress cortical electrical activity. Anesthesiology, 66: 453–464.
  • 41. Olsen ME, Vizzutti D, Marck DW, Cox AK (1993) The parasympatholytic effects of atropine sulphate and glicopyrolate in rats and rabbits Can J Vet Resear, 57: 254–258.
  • 42. Ornstein E, Young WL, Ostapkovich N (1991) Comparative effects of desflurane and isoflurane on cerebral blood flow. Anesthesiology, 75: A209.
  • 43. Ostrup RC, Luerssen TG, Marshall LE (1987) Continuous monitoring of intracranial pressure with a miniaturized fiberoptic device. J Neurosurg, 67: 206–209.
  • 44. Paxinos G, Watson C (1995) The rat nervous system. Academic Press, San Diego, London.
  • 45. Paxinos G, Watson C (1997) The rat brain in stereotaxic coordinates. Academic Press, San Diego, London.
  • 46. Pelligrino DA, Miletich DJ, Hoffman WE (1984) Nitrous oxide markedly increases cerebral cortical metabolic rate and blood flow in the goat. Anesthesiology, 60: 405–412.
  • 47. Phirman JR, Shapiro MM (1977) Modification of nitrous oxide-induced intracranial hypertension by prior induction of anesthesia. Anesthesiology, 46: 150–151.
  • 48. Piek J, Bock WI (1990) Continuous monitoring of cerebral tissue pressure in neurosurgical practice experience with 100 patients. Int Care Med, 16: 184–188.
  • 49. Punnen S, Gonzalez ER, Krieger AJ, Sapru HN (1984) Cardiac vagolytic action of some neuromuscular blockers. Pharmacol Biochem Behav, 20(1): 85–89.
  • 50. Remie R, Bertens APMG, Vaan Dongan JW, Resema JW, Vaan Wunnik GHJ (1990) Anaesthesia of the laboratory rats. In: Van Dongen JW, Resema JW, Van Wunnik GHJ (eds.). Manual of microsurgery on the laboratory rat. Elsevier, Amsterdam.
  • 51. Safo Y, Young ML, Smith DS (1985) Effects of fentanyl on local cerebral blood flow in the rat. Acta Anaesthesiol Scand, 29: 594–598.
  • 52. Sari A, Okuda Y, Takeshita H (1972) The effects of thalamonal on cerebral circulation and oxygen consumption in man. Br J Anaesth, 44: 330–334.
  • 53. Scheller MS, Nakakimura K, Fleischer JE (1990) Cerebral effects of sevoflurane in the dog: comparison with isoflurane and enflurane. Br J Anaesth, 65: 388–392.
  • 54. Scheller MS, Tateishi A, Drummond JC (1988) The effects of sevoflurane on cerebral blood flow, cerebral metabolic rate for oxygen, intracranial pressure and electroencephalogram are similar to those of isoflurane in the rabbit. Anesthesiology, 68: 548–551.
  • 55. Stephan H, Sonntag H, Schenk HD (1987) Effects of disoprivan on cerebral blood flow, cerebral oxygen consumption, and cerebral vascular reactivity. Anaesthesist, 36: 60–65.
  • 56. Stullken EH, Milde JH, Michenfe]der JD (1977) The nonlinear responses of cerebral metabolism to low concentrations of halothane, enflurane, isoflurane and thiopental. Anesthesiology, 46: 28–34.
  • 57. Todd MM, Drummond JC (1984) A comparison of the cerebrovascular and metabolic effects of halothane and isoflurane in the cat. Anesthesiology, 60: 276–282.
  • 58. Troconiz IF, Garrido MJ, Garcia E, Suarez E, Calvo R (1997) Pharmacokinetic-pharmacodynamic modeling of mivacurium in rats. J Pharm Sci, 86(2): 252–256.
  • 59. Vandesteene A, Trempont V, Engelman E (1988) Effect of propofol on cerebral blood flow and metabolism in man. Anaesthesia, 43: 42–43.
  • 60. Van-Pelt LF (1977) Ketamine and xylazine for surgical anesthesia in rats. J Am Vet Med Assoc, 171: 842–844.
  • 61. Vegfors M, Sjoberg F, Lundberg L-G, Gustafsson U, Lennmarken C (1991) Basic studies of pulse oximetry in rabbit model. Acta Anaesthesiol Scand, 35: 596–599.
  • 62. Verhaegen MJ, Todd MM, Warner DS (1992) A comparison of cerebral ischemic flow threshold during halothane/N2O and isoflurane/N2O anesthesia in rats. Anesthesiology, 76: 745–754.
  • 63. Waynforth H. Flecknell P (1992) Experimental and surgical techniques in the rat. Academic Press, London.
  • 64. Wolfensohn SK, Lloyd M (1994) Handbook of Laboratory Animal Management and Welfare. Oxford University Press.
  • 65. Xi G. Hua Y, Keep RF, Younger JG, Hoff JT (2001) Systemic complement depletion diminishes perihematomal brain edema in rats. Stroke, 32: 162–170.
  • 66. Xue M, Del Bigio MR (2000) Intracortical hemorrhage injury in rats. Stroke, 31(7): 1721–1728.
  • 67. Yuan XQ, Prough DS, Smith TL, Dewitt DS. (1988) The effects of traumatic brain injury on regional cerebral blood flow in rats. J Neurotrauma, 5(4): 289–301.

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

bwmeta1.element.agro-article-79bc4547-0e43-4e70-9171-61e5f3cddfc8
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.