OESOPHAGEAL TEMPERATURE MONITORING DURING GENERAL ANAESTHESIA

Hamid Abdulnabi

doi:10.33762/bsurg.2006.55363

Abstract

This study aimed to demonstrate the oesophageal temperature changes with the time during general anaesthesia for the routine surgical work, and to see the effects of patient’s gender or age, and the effects of neuromuscular blockade on these changes, also to compare oesophageal temperature changes with mean skin temperature changes during general anaesthesia, and to assess the problem of unintentional intraoperative hypothermia with its complications in the postanaesthetic recovery room. Fifty three ASA (I-II) unpremedicated randomly selected patients (26 males and 27 females) undergoing different routine elective surgical operations under general anaesthesia in the University Hospital Medical College in Baghdad between August -September 2001. Anaesthesia was induced by intravenous (iv) thiopentone 4-5 mg /kg and fentanyl 1-2 g/kg, and maintained with either 2-3 % halothane in oxygen without neuromuscular blockade in spontaneously ventilated by mask (4 patients)or manually assisted ventilation through a tube in 17 patients, while it was maintained by 0.5-1% halothane in oxygen and the muscle paralysis was done by either suxamethonium 1 mg/kg bolus iv followed by infusion of 4-10mg\min. of 0.1% suxamethonium solution to 16 patients, or by iv pancuronium 0.1 mg /kg (16patients), then endotracheal intubation was done and ventilation was mechanically controlled. Neostigmine 40g/kg and atropine 20 g/kg were given iv at the ends of operation to reverse residual blockade of pancuronium where it was given. Monitoring of the oesophageal and skin temperatures was started ten minutes after induction of anaesthesia as a baseline, repeated every ten minutes until the end of halothane administration and the last measurements were taken just before discharging the patient from the recovery room, other vital signs were also monitored like noninvasive blood pressure, ECG, and pulse oximetry at the perioperative periods. The means for the ambient temperature and the relative humidity of the operating theatre were also recorded. Postanaesthetic shivering when observed, was scored (0-3), pulse oximetry was used to assess oxygenation status. The postanaesthetic recovery time was measured from the moment of closing the halothane vaporizer at the end of the operation until the patient got 10 degrees according to Aldrete &Kronlik postanaesthetic recovery score. Oesophageal temperature increase above the baseline occurred in 7.54% (4/53) of the patients with mean increase was 1.035C  0.797 (SD) range was 0.2-3.4C, while the temperature decrease below the baseline occurred in 92.45 % ( 49/53) of the patients, with mean decrease was 1.7 C  0.67 (SD), the range was 1 - 3.4 C .The decrease became significant ( P < 0.05) at 20-150 minutes after induction in oesophageal temperature and at 30-140 minutes in mean skin temperature. At all time periods after induction the oesophageal temperature readings were significantly (P<0.05) above those of the mean skin temperature. Changes in oesophageal temperature showed no significant difference between males and females, but there was significant (P<0.05) difference between different age groups up to 90 minutes after induction, however significant differences were seen between patients who had spontaneous or assisted ventilation with 2-3% halothane in oxygen, and those who received muscle relaxants in addition to 0.5-1% halothane in oxygen with controlled ventilation

Highlights

Under normal conditions the temperature of the body is controlled within 0.4oC of its set-point (37oC) which is a condition necessary to maintain the vital cellular metabolic processes
This study aimed to demonstrate oesophageal temperature changes with time during general anaesthesia in routine surgical operations and to see the effects of patent's age and gender and the neuromuscular blockade on these changes
Anaesthesia Technique: There was no routine premedication, and anaesthesia was induced intravenously (iv) by thiopentone 2.5% in a dose of 4-5 mg/kg body mass, fentanyl 1-2, and anaesthesia was maintained by 0.51% halothane in oxygen, with the muscle relaxation was achieved by either intravenous (iv) pancuronium bromide 0.1 mg/kg (16 patients),or by (iv) suxamethonium 1mg/kg followed by infusion 4-10mg/min as 0.1% solution of suxamethonium (16 patients) and the remaining 21 patients were ventilated with oxygen supplemented by end tidal halothane 2-3% halothane without muscle relaxants and ventilated either spontaneously by mask in 4 patients, or assisted manually through endotracheal tube in 17 patients

Summary

Introduction

Under normal conditions the temperature of the body is controlled within 0.4oC of its set-point (37oC) which is a condition necessary to maintain the vital cellular metabolic processes. Mild hypothermia occurring during general anesthesia (i.e a drop in core temperature of between 1°C and 3°C) is very common3 This is caused by (a) thermally sensitive cells located throughout the body, principally the skin, brain, spinal cord and certain central core tissues. The cold information is transmitted via A-delta fibers and warm influx via unmyelinated C-fibers which are responsible for transmission of pain sensation This explains why intense thermogenic stimulation cannot be differentiated from sharp pain. These thermal inputs are transferred by the ascending spinothalamic tracts to the hypothalamus to be integrated and internal redistribution of heat within the body. The benefit of body temperature monitoring through the oesophagus during general anaesthesia where no routine active warming measures are taken, will be investigated in this study. To compare the oesophageal temperature changes with those of mean skin temperature during general anaesthesia and finely to assess the problem of intraoperative unintentional hypothermia and it's complications in the postanesthetic recovery room

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Conclusion