L. Martoft scite author profile

L. Martoft

4Publications

92Citation Statements Received

21Citation Statements Given

How they've been cited

133

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Affiliations

AstraZeneca (Sweden), Royal Agricultural University

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Effects of CO₂ anaesthesia on central nervous system activity in swine

et al. 2002

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SummaryT he objective of the study was to exam ine the changes in central nervous system (CNS) activity and physical behaviour during induction and awakening from CO 2 anaesthesia. Two studies, each using pigs immersed into 90% CO 2 gas for a period of 60 s were performed. In study 1, we monitored middle latency auditory evoked potentials (changes in latencies, amplitudes and a depth of anaesthesia index), electroencephalographic parameters (delta, theta, alpha and beta electroencephalographic power and 95% spectral edge frequency) and heart rate; and in study 2, we monitored body movements and arterial and venous partial pressure of CO 2 and O 2 . No behavioural signs of distress were observed during the early part of the induction. T he swine exhibited muscular activity from 13±30 s after induction-start as well as during awak ening from anaesthesia, possibly because of a transitory weaker suppression of the brain stem than of the cortex. T he CNS and blood gas param eters started to change from the very start of induction. T he CNS suppression lasted only approxim ately one minute after the end of the induction period. T he two studies indicated a good tem poral relationship between changes in amplitude, depth of anaesthesia index, spectral edge frequency, and arterial P CO 2 during the induction period.

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Middle-latency auditory evoked potentials during induction of thiopentone anaesthesia in pigs

et al. 2001

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A method is described for measuring middle-latency auditory evoked potentials (MLAEP) in consciously awake, non-sedated pigs during the induction of thiopentone anaesthesia (0.6 ml/kg, 2.5% thiopentone solution). It was done by using autoregressive modelling with an exogenous input (ARX). The ability to perceive pain during the induction was compared with (1) the changes in latencies and amplitudes of the MLAEP, (2) the change in a depth of anaesthesia index based on the ARX-model and (3) the change in the 95% spectral edge frequency. The pre-induction MLAEP was easily recordable and looked much like the one in man, dogs and rats. The temporal resolution in the ARX method was sufficiently high to describe the fast changes occurring during induction of thiopentone anaesthesia. As previously reported from studies in man, dogs and rats, induction of thiopentone anaesthesia resulted in significantly increased latencies and decreased amplitudes of the MLAEP trace as well as in a significantly reduced depth of anaesthesia index and spectral edge frequency. None of the changes, however, related well to the ability to react to a painful stimulus. Whether an ARX-based depth of anaesthesia index designed especially for pigs might be better than the present index (designed for man) for assessing depth of anaesthesia must await the results of further studies.

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CO₂ induced acute respiratory acidosis and brain tissue intracellular pH: a ³¹P NMR study in swine

et al. 2003

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High concentration carbon dioxide (CO(2)) is used to promote pre-slaughter anaesthesia in swine and poultry, as well as short-lasting surgical anaesthesia and euthanasia in laboratory animals. Questions related to animal welfare have been raised, as CO(2) anaesthesia does not set in momentarily. Carbon dioxide promotes anaesthesia by lowering the intracellular pH in the brain cells, but the dynamics of the changes in response to a high concentration of CO(2) is not known. Based on (31)P NMR spectroscopy, we describe CO(2)-induced changes in intracellular pH in the brains of five pigs inhaling 90% CO(2) in ambient air for a period of 60 s, and compare the results to changes in arterial blood pH, P(CO2), O(2) saturation and HCO(3)(-) concentration. The intracellular pH paralleled the arterial pH and P(CO2) during inhalation of CO(2); and it is suggested that the acute reaction to CO(2) inhalation mainly reflects respiratory acidosis, and not metabolic regulation as for example transmembrane fluxes of H(+)/HCO(3)(-). The intracellular pH decreased to approximately 6.7 within the 60 s inhalation period, and the situation was metabolically reversible after the end of CO(2) inhalation. The fast decrease in intracellular pH supports the conclusion that high concentration CO(2) leads to anaesthesia soon after the start of inhalation.

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CO₂-stunning in pigs

et al. 2010

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L. Martoft

Effects of CO₂ anaesthesia on central nervous system activity in swine

Middle-latency auditory evoked potentials during induction of thiopentone anaesthesia in pigs

CO₂ induced acute respiratory acidosis and brain tissue intracellular pH: a ³¹P NMR study in swine

CO₂-stunning in pigs

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L. Martoft

Effects of CO2 anaesthesia on central nervous system activity in swine

Middle-latency auditory evoked potentials during induction of thiopentone anaesthesia in pigs

CO2 induced acute respiratory acidosis and brain tissue intracellular pH: a 31P NMR study in swine

CO2-stunning in pigs

Contact Info

Product

Resources

About

Effects of CO₂ anaesthesia on central nervous system activity in swine

CO₂ induced acute respiratory acidosis and brain tissue intracellular pH: a ³¹P NMR study in swine

CO₂-stunning in pigs