The association between regional body composition and metabolic outcomes in athletes with spinal cord injury

STUDY DESIGN: Cross-sectional study comparing athletes with spinal cord injury (SCI) and age and body mass index matched able-bodied controls (AB). OBJECTIVE: To examine the impact of exercise training on the relation between whole body, regional and intermuscular adipose tissue (IMAT) and glucose tolerance, insulin action and lipid profile. SETTING: University Research Laboratory, USA. METHODS: Fourteen college-aged athletes with SCI (seven men; duration of injury 16.5+/-5.7 years, level of injury T5-L5) and 17 sedentary AB (eight men) were assessed for body composition via dual-energy X-ray absorptiometry (DXA) and magnetic resonance imaging. Insulin sensitivity index (ISI) was determined via 2-h oral glucose challenge; standard lipid profile was determined from fasting blood samples. RESULTS: Although ISI was 30% higher in SCI, there were no significant differences between groups in glucose and insulin responses or in lipid measures. Adjusting for absolute and relative thigh IMAT area, fasting insulin (13.8+/-5.3 microIU, 16.3+/-5.6 microIU; P<0.05; SCI vs AB respectively) and ISI (4.0+/-1.4, 3.1+/-1.3; P<0.05) were significantly better among SCI athletes compared to AB. Measures of adiposity did not correlate with glucose response or most lipid measures. Within SCI and AB, respectively, ISI correlated strongly (all P<0.05) with absolute (r = -0.70, -0.54) and relative IMAT (r = -0.54, -0.50), than with trunk (r = -0.62, -0.64) and whole body fat mass (r = -0.61, -0.64). CONCLUSION: Habitual physical activity can maintain insulin sensitivity in SCI compared to sedentary AB controls. Total body fat mass, central adiposity and thigh IMAT appear to impact risk for metabolic disease in SCI individuals with IMAT playing a larger role in SCI than AB.     

Tissue heat content and distribution during and after cardiopulmonary bypass at 17 degrees C.

We measured afterdrop and peripheral tissue temperature distribution in eight patients cooled to approximately 17 degrees C during cardiopulmonary bypass and subsequently rewarmed to 36.5 degrees C. A nasopharyngeal probe evaluated trunk and head temperature and heat content. Peripheral tissue temperature (arm and leg temperature) and heat content were estimated using fourth-order regressions and integration over volume from 30 tissue and skin temperatures. Peripheral tissue temperature decreased to 19.7+/-0.9 degrees C during bypass and subsequently increased to 34.3+/-0.7 degrees C during 104+/-18 min of rewarming. The core-to-peripheral tissue temperature gradient was -5.9+/-0.9 degrees C at the end of cooling and 4.7+/-1.5 degrees C at the end of rewarming. The core-temperature afterdrop was 2.2+/-0.4 degrees C and lasted 89+/-15 min. It was associated with 1.1+/-0.7 degrees C peripheral warming. At the end of cooling, temperatures at the center of the upper and lower thigh were (respectively) 8.0+/-5.2 degrees C and 7.3+/-4.2 degrees C cooler than skin temperature. On completion of rewarming, tissue at the center of the upper and lower thigh were (respectively) 7.0+/-2.2 degrees C and 6.4+/-2.3 degrees C warmer than the skin. When estimated systemic heat loss was included in the calculation, redistribution accounted for 73% of the afterdrop, which is similar to the contribution observed previously in nonsurgical volunteers. IMPLICATIONS: Temperature afterdrop after bypass at 17 degrees C was 2.2+/-0.4 degrees C, with approximately 73% of the decrease in core temperature resulting from core-to-peripheral redistribution of body heat. Cooling and rewarming were associated with large radial tissue temperature gradients in the thigh.     

Efficacy of Two Methods for Reducing Postbypass Afterdrop

Background: Afterdrop, defined as the precipitous reduction in core temperature after cardiopulmonary bypass, results from redistribution of body heat to inadequately warmed peripheral tissues. The authors tested two methods of ameliorating afterdrop: (1) forced-air warming of peripheral tissues and (2) nitroprusside-induced vasodilation.

Methods: Patients were cooled during cardiopulmonary bypass to approximately 32[degrees]C and subsequently rewarmed to a nasopharyngeal temperature near 37[degrees]C and a rectal temperature near 36[degrees]C. Patients in the forced-air protocol (n = 20) were assigned randomly to forced-air warming or passive insulation on the legs. Active heating started with rewarming while undergoing bypass and was continued for the remainder of surgery. Patients in the nitroprusside protocol (n = 30) were assigned randomly to either a control group or sodium nitroprusside administration. Pump flow during rewarming was maintained at 2.5 l [middle dot] m-2 [middle dot] min-1 in the control patients and at 3.0 l [middle dot] m-2 [middle dot] min-1 in those assigned to sodium nitroprusside. Sodium nitroprusside was titrated to maintain a mean arterial pressure near 60 mmHg. In all cases, a nasopharyngeal probe evaluated core (trunk and head) temperature and heat content. Peripheral compartment (arm and leg) temperature and heat content were estimated using fourth-order regressions and integration over volume from 18 intramuscular needle thermocouples, nine skin temperatures, and "deep" hand and foot temperature.

Results: In patients warmed with forced air, peripheral tissue temperature was higher at the end of warming and remained higher until the end of surgery. The core temperature afterdrop was reduced from 1.2 +/- 0.2[degrees]C to 0.5 +/- 0.2[degrees]C by forced-air warming. The duration of afterdrop also was reduced, from 50 +/- 11 to 27 +/- 14 min. In the nitroprusside group, a rectal temperature of 36[degrees]C was reached after 30 +/- 7 min of rewarming. This was only slightly faster than the 40 +/- 13 min necessary in the control group. The afterdrop was 0.8 +/- 0.3[degrees]C with nitroprusside and lasted 34 +/- 10 min which was similar to the 1.1 +/- 0.3[degrees]C afterdrop that lasted 44 +/- 13 min in the control group.     

EFFECTS OF ENFLURANE AND ISOFLURANE IN AIR-OXYGEN ON CHANGES IN THERMAL BALANCE DURING AND AFTER SURGERY

The temperatures in the aural canal (core), skeletal muscleand skin surface were measured during anaesthesia and surgeryin 32 healthy females undergoing total abdominal hysterectomyand for 4 h after operation. The patients were allocated randomlyto one of four groups according to the end-tidal concentrationof volatile anaesthetic: 1 MAC isoflurane, 1 MAC enflurane,1.8 MAC isoflurane and 1.8 MAC enflurane. The lungs were ventilatedwith an air-oxygen mixture. Neuromuscular block was producedwith pancuronium. Room temperature and i.v. fluid administrationwere standardized. Aural canal, muscle and mean skin temperaturesdecreased significantly in all groups during surgery (P <0.001). The decrease in core and muscle temperatures, and meanbody heat was significantly greater in the 1.8 MAC groups thanin the 1 MAC groups for both volatile agents (P < 0.001).However, there was a significantly greater decrease in coretemperature and mean body heat in the isoflurane compared withthe enflurane group (P < 0.026). Body temperature returnedto preoperative values during the recovery period. There wasa significantly greater rate of rewarming during the first 1h of recovery in the 1.8 MAC groups compared with the 1 MACequivalent (P < 0.001), and this was independent of the volatileagent used. The present results are compared with those reportedpreviously in which nitrous oxide was added to the volatileagents. The decrease in body temperature depends upon the concentrationof vapour used. However, it appears that isoflurane, withoutnitrous oxide, caused greater loss of body heat than enflurane.     

Relationship between ambient temperature and heat flux in the scrotal skin

Excessive scrotal heating or cooling may lead to the cessation of spermatogenesis. Data regarding heat exchange rates in scrotal skin can be used to control testicular temperature within the appropriate range. Heat flux (HF) in the scrotal skin surface is generated based on the surrounding environment. This study aims to elucidate the HF of scrotal skin by varying ambient temperature. Twenty college students including seven varicoceles volunteered as the subjects (mean age: 22.95 +/- SD 1.96 years; height: 175.00 +/- 5.17 cm; weight: 68.40 +/- 8.65 kg; body mass index: 22.28 +/- 2.15), and participated in the experiments from September 11 to October 4, 2006. The environmental temperature was controlled at 20 degrees C and 25 degrees C in the first and second experiment respectively. The HF and skin temperature on both sides of the scrotal surface were measured for 60 min in the environmental chamber. The results revealed that the HF was 87.64 +/- 12.69 W/m(2) and 78.91 +/- 12.09 W/m(2) in the left and right side of the scrotum respectively. The scrotal skin temperature (SST) was 30.28 +/- 0.75 degrees C and 30.24 +/- 0.62 degrees C on the left and right side of the scrotum in the 20 degrees C environment respectively. In the 25 degrees C environment the HF was 53.54 +/- 8.86 W/m(2) and 45.25 +/- 8.32 W/m(2), and the SST was 32.29 +/- 0.61 degrees C and 32.07 +/- 0.36 degrees C on the left and right side of the scrotum respectively. The cooling source power to decrease testicular temperature is suggested at 290 W/m(2). This suggested value could be adopted a cooling device as clinical therapy for a heat stress patient to decrease testicular temperature affecting spermatogenesis.     

Core cooling by central venous infusion of ice-cold (4 degrees C and 20 degrees C) fluid: isolation of core and peripheral thermal compartments

BACKGROUND: Central venous infusion of cold fluid may be a useful method of inducing therapeutic hypothermia. The aim of this study was to quantify systemic heat balance and regional distribution of body heat during and after central infusion of cold fluid. METHODS: The authors studied nine volunteers, each on two separate days. Anesthesia was maintained with use of isoflurane, and on each day 40 ml/kg saline was infused centrally over 30 min. On one day, the fluid was 20 degrees C and on the other it was 4 degrees C. By use of a tympanic membrane probe core (trunk and head) temperature and heat content were evaluated. Peripheral compartment (arm and leg) temperature and heat content were estimated with use of fourth-order regressions and integration over volume from 18 intramuscular thermocouples, nine skin temperatures, and "deep" hand and foot temperature. Oxygen consumption and cutaneous heat flux estimated systemic heat balance. RESULTS: After 30-min infusion of 4 degrees C or 20 degrees C fluid, core temperature decreased 2.5 +/- 0.4 degrees C and 1.4 +/- 0.2 degrees C, respectively. This reduction in core temperature was 0.8 degrees C and 0.4 degrees C more than would be expected if the change in body heat content were distributed in proportion to body mass. Reduced core temperature resulted from three factors: (1) 10-20% because cutaneous heat loss exceeded metabolic heat production; (2) 50-55% from the systemic effects of the cold fluid per se; and (3) approximately 30% because the reduction in core heat content remained partially constrained to core tissues. The postinfusion period was associated with a rapid and spontaneous recovery of core temperature. This increase in core temperature was not associated with a peripheral-to-core redistribution of body heat because core temperature remained warmer than peripheral tissues even at the end of the infusion. Instead, it resulted from constraint of metabolic heat to the core thermal compartment. CONCLUSIONS: Central venous infusion of cold fluid decreases core temperature more than would be expected were the reduction in body heat content proportionately distributed. It thus appears to be an effective method of rapidly inducing therapeutic hypothermia. When the infusion is complete, there is a spontaneous partial recovery in core temperature that facilitates rewarming to normothermia.     

Core Cooling by Central Venous Infusion of Ice-cold (4°C and 20°C) Fluid: Isolation of Core and Peripheral Thermal Compartments

Background: Central venous infusion of cold fluid may be a useful method of inducing therapeutic hypothermia. The aim of this study was to quantify systemic heat balance and regional distribution of body heat during and after central infusion of cold fluid.

Methods: The authors studied nine volunteers, each on two separate days. Anesthesia was maintained with use of isoflurane, and on each day 40 ml/kg saline was infused centrally over 30 min. On one day, the fluid was 20[degrees]C and on the other it was 4[degrees]C. By use of a tympanic membrane probe core (trunk and head) temperature and heat content were evaluated. Peripheral compartment (arm and leg) temperature and heat content were estimated with use of fourth-order regressions and integration over volume from 18 intramuscular thermocouples, nine skin temperatures, and "deep" hand and foot temperature. Oxygen consumption and cutaneous heat flux estimated systemic heat balance.

Results: After 30-min infusion of 4[degrees]C or 20[degrees]C fluid, core temperature decreased 2.5 +/- 0.4[degrees]C and 1.4 +/- 0.2[degrees]C, respectively. This reduction in core temperature was 0.8[degrees]C and 0.4[degrees]C more than would be expected if the change in body heat content were distributed in proportion to body mass. Reduced core temperature resulted from three factors: (1) 10-20% because cutaneous heat loss exceeded metabolic heat production; (2) 50-55% from the systemic effects of the cold fluid per se; and (3) approximately 30% because the reduction in core heat content remained partially constrained to core tissues. The postinfusion period was associated with a rapid and spontaneous recovery of core temperature. This increase in core temperature was not associated with a peripheral-to-core redistribution of body heat because core temperature remained warmer than peripheral tissues even at the end of the infusion. Instead, it resulted from constraint of metabolic heat to the core thermal compartment.     

Thermoregulatory responses to exercise and warm water immersion in physically trained men with tetraplegia

OBJECTIVE: To compare thermoregulatory responses of highly trained men who are tetraplegic during 40 min exercise at 65% [Vdot]O(2) peak and 60 min immersion in 39 degrees C water. METHODS: Four physically trained men who are tetraplegic participated in three laboratory visits. The first visit involved familiarisation and then determination of [Vdot]O(2) peak using open circuit spirometry during an incremental test to exhaustion with each man propelling his sport wheelchair on a motor driven treadmill. The order of second and third visits was randomly allocated. Visit 2 involved 40 min of exercise at 65% [Vdot]O(2) peak propelling each man's sport wheelchair on treadmill. Visit 3 involved sitting immersed to nipple line in 39 degrees C water for 60 min. Venous blood was obtained pre, during and after each intervention and analyzed for haemoglobin, haematocrit and changes in plasma volume were calculated. Separated plasma was analyzed for noradrenalin and adrenalin (high performance liquid chromatography). Heart rate, rectal temperature, and sweat rate estimated from a sweat capsule placed on forehead (dew point hygrometry) were recorded throughout. RESULTS: [Vdot]O(2) peak and HR max of these subjects were 1.14+/-0.16 l.min(-1) and 99+/-4 b.min(-1) respectively. Heart rate preimmersion was 67+/-4 b.min(-1) rising to 75+/-4 b.min(-1) after 40 min and 87+/-3 b.min(-1) after 60 min immersion. Heart rate was 68+/-3 b.min(-1) pre-exercise rising to 91+/-5 b.min(-1) after 40 min exercise. Rectal temperature rose from 35.97+/-0.30 degrees C pre immersion to 37.32+/-0.51 degrees C after 60 min immersion, and from 36.42+/-0.20 degrees C pre-exercise to 36.67+/-0.19 degrees C after 40 min exercise. Haemoconcentration occurred during 40 min of exercise and haemodilution occurred throughout 60 min of water immersion. Three participants demonstrated no sweating on the forehead during immersion or exercise. One subject commenced sweating after 20 min exercise and after 5 min of immersion. CONCLUSION: Compared to exercise, immersion was associated with a lower heart rate, a lower plasma noradrenalin concentration and an expanded plasma volume. When considering exercise or warm water immersion as therapeutic modalities in men who are tetraplegic, attention should be paid to heat gain and changes in plasma volume.     

The effects of two rewarming strategies on heat balance and metabolism after coronary artery bypass surgery with moderate hypothermia

BACKGROUND: Postoperative hypothermia is common in cardiac surgery with hypothermic cardiopulmonary bypass (CPB). This trial was designed to evaluate whether rewarming over the normal bladder temperature (over 37 degrees C) at the end of hypothermic CPB combined with passive heating methods after CPB might result in a better heat balance, lower energy expenditure (EE) and decrease of disturbances in oxygen balance compared to only rewarming the patients to a bladder temperature of 35-37 degrees C. METHODS: A prospective, randomized controlled clinical study was performed in 38 patients scheduled for elective coronary artery bypass surgery. Twenty patients (group C) were rewarmed to a bladder temperature of 35-37 degrees C at the end of hypothermic (28 degrees C) CPB. Eighteen patients (group W) were rewarmed to a bladder temperature of 37-38.5 degrees C. RESULTS: At the end of CPB, the bladder temperature was 36.2+/-0.7 degrees C (mean+/-SD) in group C and 37.9+/-0.5 degrees C in group W. After half an hour's stay in the ICU, the mean body temperature (MBT) was 35.1+/-0.6 degrees C in group C and 36.6+/-0.7 degrees C in group W. During the following five hours, MBT increased to 37.4+/-0.8 degrees C in group C and to 38.0+/-0.6 degrees C in the other group. The peak value of EE in the ICU was 1.73+/-0.44 (group C) vs 1.35+/-0.29 (W/kg) (group W) (P=0.003). EE was significantly (P=0.044) higher in group C than in the other group between 1.5 and 5.5 h in the ICU. The increased energy expenditure due to heat production was associated with an increase in O2 consumption (VO2) 61.6+/-30.4% vs 25.2+/-24.1%, (peak values) compared to the basal values of the two groups measured before anesthesia (between groups P<0.001). Between 1.5 and 5.5 h in the ICU, group C had significantly higher VO2 (P=0.026), CO2 production (P=0.017), venous pCO2 (P<0.001) and minute ventilation (p=0.014) than group W. Venous pH was lower (P<0.001) in group C. The peak value of oxygen extraction was also higher (P=0.045) in group C. On the other hand, the lowest value of venous oxygen saturation was higher (P=0.04) in group W. CONCLUSION: With rewarming the patients at the end of CPB to a bladder temperature of over 37 degrees C combined with passive heating methods after CPB, it was possible to decrease EE and VO2 compared to the control group (rewarmed to bladder temperature of 35-37 degrees C) after coronary artery bypass surgery with moderate hypothermia.     

Long-term survival, morphology and in vitro function of isolated pig islets under different culture conditions.

BACKGROUND: Islet culture aims to optimize islet survival and to reduce islet immunogenicity. To achieve these objectives, culture periods at 37 degrees C and 22-24 degrees C are mainly used. METHODS: This study compares the influence of donor age (juvenile vs. adult), temperature (22 degrees C vs. 37 degrees C), and serum supplementation (10% newborn calf serum [NCS] with 10% pig serum) on morphological integrity and in vitro function of porcine islets during long-term culture (LTC). RESULTS: After 21 days at 22 degrees C, the survival rate of cultured islets isolated from juvenile donors was lower than of adult islets (23+/-0.9% vs. 88+/-2.8%, P<0.001). Compared with 37 degrees C, LTC at 22 degrees C increased survival of adult islets and DNA recovery (92+/-2.5% vs. 45+/-4.8%, P<0.001; 72+/-4.1% vs. 30+/-5.1%, P<0.001) and reduced viability (62+/-8% vs. 89+/-5%, P<0.05). LTC at 22 degrees C was associated with a reduction of insulin content (85+/-9 vs. 152+/-10 microU/islet equivalents [IEQ], P<0.01), 24 hr-insulin secretion (82+/-7 vs. 552+/-91 microU/ day/IEQ, P<0.001), and integrated dynamic insulin response to glucose (1093+/-124 vs. 3074+/-708 microU/60 min/100 IEQ, P<0.05), compared with 37 degrees C LTC. Histologic analysis revealed disintegration of islet periphery after 22 degrees C, whereas smoothly shaped islets were present after 37 degrees C LTC. Integrity after 14 days at 37 degrees C was significantly better preserved when medium CMRL 1066 was supplemented with 10% porcine serum, compared with 10% NCS (40+/-2.3% vs. 21+/-6.7%, P<0.05), contrasting with 22 degrees C (52+/-4.0% vs. 59+/-3.7%, not significant). CONCLUSIONS: This study demonstrates that survival of cultured porcine islets is increased at 22 degrees C, whereas in vitro function and viability are better preserved at 37 degrees C. Survival at 37 degrees C can be improved by adding homologous serum to the medium.     

Feasibility,accuracy and optimal location for oesophageal core temperature measurements using the ProSeal laryngeal mask airway drain tube

We determined the feasibility, accuracy and optimal location of oesophageal core temperature measurements using the ProSeal laryngeal mask airway drain tube. Thirty normothermic anaesthetized ventilated adults (ASA 1 to 2, aged 18 to 80 years) were studied. Temperatures were recorded using a thermistor at six different locations (middle of drain tube and at 0 to 20 cm distal to the drain tube in 5 cm increments) and compared to nasopharyngeal (thermistor) and aural (infrared tympanic thermometer) reference core temperatures. The temperature probe was successfully inserted into the oesophagus in all patients at the first attempt. Oesophageal temperature increased with depth from 0 to 5 cm (35.2 v 35.9, P < 0.0001) and 5 to 10 cm (35.9 v 36.3, P < 0.01), but was unchanged from 10 to 15 cm (36.3 v 36.6) and 15 to 20 cm (36.6 v 36.7). Aural temperature was higher than nasopharyngeal temperature (36.8 v 36.0, P < 0.0001). Aural temperature was 0.89 to 1.59 degrees C higher than the oesophagus at 0 to 5 cm and 0.21 to 0.30 degree C higher than the oesophagus at 15 to 20 cm. Nasopharyngeal temperature was 0.06 to 0.76 degree C higher than the oesophagus at 0 to 5 cm and 0.62 to 0.84 degree C lower than the oesophagus at 15 to 20 cm. The lowest temperature was in the mid-point of the drain tube (34.7). We conclude that oesophageal core temperature measurement is feasible and accurate using the ProSeal laryngeal mask airway. The optimal location for the temperature probe is at 15 to 20 cm.     

Chronic treatment with antipsychotics enhances intraoperative core hypothermia

Antipsychotics can induce hypothermia, but intraoperative temperature regulation in schizophrenic patients taking antipsychotics remains unclear. We investigated intraoperative temperature regulation and postoperative shivering in chronic schizophrenic patients receiving antipsychotics. We studied 30 schizophrenic patients and 30 control patients who underwent orthopedic surgery. Tympanic membrane temperatures (35.7 degrees C +/- 0.5 degrees C, 35.6 degrees C +/- 0.5 degrees C, 35.6 degrees C +/- 0.4 degrees C, 35.5 degrees C +/- 0.4 degrees C, 35.4 degrees C +/- 0.5 degrees C, and 35.4 degrees C +/- 0.3 degrees C) 15, 30, 45, 60, 75, and 90 min, respectively, after induction in schizophrenic patients were significantly (P < 0.001) lower than those (36.5 degrees C +/- 0.5 degrees C, 36.4 degrees C +/- 0.5 degrees C, 36.3 degrees C +/- 0.4 degrees C, 36.2 degrees C +/- 0.5 degrees C, 36.2 degrees C +/- 0.4 degrees C, and 36.1 degrees C +/- 0.4 degrees C) in control patients. Mean skin temperatures (31.1 degrees C +/- 0.4 degrees C [P = 0.008], 31.1 degrees C +/- 0.3 degrees C [P = 0.007], and 31.1 degrees C +/- 0.2 degrees C [P = 0.006]) 60, 75, and 90 min, respectively, after induction in schizophrenic patients were significantly lower than those (31.5 degrees C +/- 0.3 degrees C, 31.5 degrees C +/- 0.3 degrees C, and 31.5 degrees C +/- 0.3 degrees C) in control patients. Four of 30 schizophrenic patients and 7 of 30 control patients developed postanesthesia shivering. There were no significant differences within 1 h after tracheal extubation in tympanic membrane temperatures between patients who shivered and those who did not shiver. In conclusion, chronic schizophrenic patients were more hypothermic during anesthesia. The incidence of postanesthesia shivering was not significantly increased. IMPLICATIONS: Antipsychotics inhibit autonomic thermoregulation. This is caused by decreased heat production, increased heat loss, and impaired central action at the hypothalamus. Thus, schizophrenic patients receiving antipsychotics may have impaired intraoperative temperature regulation.     

Effects of oral clonidine premedication and postoperative i.v. infusion on haemodynamic and adrenergic responses during recovery from anaesthesia

The effects of clonidine, a central alpha 2-adrenoreceptor agonist, on haemodynamic and catecholamine changes were assessed during emergence from anaesthesia, a period which is associated with increased sympathetic nervous discharge, hypertension and tachycardia. According to a double-blind randomized design, 32 patients received either clonidine, preoperatively given by oral route (3.5 micrograms.kg-1) and postoperatively by i.v. infusion (0.3 microgram.kg-1.h-1), or a placebo. Perioperative management was similar in both groups. Measurements were made in the recovery room, before starting clonidine or placebo infusions for evaluation of clonidine premedication, and then during infusion as follows: when core temperature reached 37 degrees C; then 2 h, and 6 h later. Prior to starting infusions, mean blood pressure (88 +/- 15 vs 103 +/- 14 mmHg) (11.7 +/- 2.0 vs 13.7 +/- 1.9 kPa), heart rate (67 +/- 8 vs 87 +/- 17 beats.min-1) and plasma norepinephrine levels (462 +/- 393 vs 615 +/- 361 pg.ml-1) were lower in the clonidine group. Only at the latest measurement (6 h after core temperature reached 37 degrees C) did clonidine elicit significant effects. The values during clonidine infusion compared to placebo were at this time: mean blood pressure (73 +/- 10 vs 86 +/- 13 mmHg) (9.7 +/- 1.3 vs 11.5 +/- 1.7 kPa), heart rate (71 +/- 6 vs 93 +/- 13 beats.min-1) and plasma norepinephrine levels (240 +/- 224 vs 451 +/- 111 pg.ml-1). Our results suggest that: 1) preoperative clonidine may improve the haemodynamic profile associated with anaesthetic discontinuation, but 2) i.v. infusion (0.3 microgram.kg-1.h-1) did not prolong this effect during the early postoperative period in the face of the sympathetic nervous discharge of recovery.     

Oxygen uptake during recovery following naloxone. Relationship with intraoperative heat loss.

The increased metabolic and respiratory demand during naloxone recovery from opioid-based anesthesia could be related to the return of thermoregulation in hypothermic patients and thus be avoided by preventing intraoperative hypothermia. In this study, we measured O2 uptake (VO2) during naloxone-induced recovery in two groups of patients to determine the effect of intraoperative heat loss on postoperative VO2 changes. In seven patients, intraoperative hypothermia was prevented (normothermic group), whereas hypothermia was allowed to develop in seven other patients (hypothermic group). Core and skin temperatures were measured throughout the study to calculate changes in body heat content. Before naloxone antagonism of fentanyl-supplemented anesthesia, core temperature (mean +/- SEM) was 36.8 +/- 0.1 degrees C in the normothermic group and 34.2 +/- 0.2 degrees C in the hypothermic group (P less than 0.001). After titrated administration of naloxone during recovery, VO2 and minute ventilation (VE) increased in the hypothermic group, by 114 +/- 37% and 97 +/- 52% respectively (P less than 0.05), with a three-fold increase in four patients. In the normothermic group, VO2 increased significantly less (25 +/- 5%), without any significant change in VE. The change in VO2 and VE was significantly greater in patients who were hypothermic. VO2 was integrated throughout the recovery period to calculate recovery energy expenditure. Recovery energy expenditure and intraoperative heat loss were highly correlated (r = 0.88; P less than 0.01). This study demonstrates that the metabolic and respiratory stresses associated with naloxone-induced recovery from opioid-based anesthesia depend on the intraoperative heat loss and can therefore be reduced by preventing intraoperative hypothermia.     

Evaluation of sprint exercise testing protocols in wheelchair athletes

STUDY DESIGN: Comparison of five different exercise testing protocols with different speeds on a treadmill with seven wheelchair athletes. OBJECTIVE: To determine which speed and duration in an exercise protocol is best to test wheelchair athletes performing sprint races on a track. SETTING: Swiss Paraplegic Centre, Nottwil, Switzerland. METHODS: Three elite and four junior wheelchair athletes (18.7+/-6.8 years, 52.1+/-9.7 kg and 165.3+/-19.3 cm) performed five different exercise testing protocols at different speeds on a treadmill until exhaustion. Maximal effort treadmill (0.7% incline) testing protocols were performed using three timeframes. The first was focussing on short duration tests (S1 and S2) where incremental increases in velocity (0.42 and 0.1 m.s(-1)) were required from a stationary start. The second were medium duration tests (M1 and M2) where the athlete started at their 200 m and 800 m personal best time (mean velocities) and then had the velocity increased 1 km.h(-1) by every 10 and 60 s respectively. The long duration test (L) started at 14 km.h(-1) and velocity was increased by 2 km.h(-1) every 120 s. Maximal heart rate, maximal concentration of lactate, maximal speed, and maximal duration of the test were measured. RESULTS: The highest concentration of lactate and the highest heart rates were measured in the longest tests. CONCLUSION: During maximal effort testing wheelchair athletes are able to produce higher lactate concentrations when tested for longer duration. Post test lactate assessments provide little information in short duration testing protocols. Sequential lactate assessments post-test may provide additional information on the rate of recovery for middle distance wheelchair athletes and warrants further investigation.     

Surface-induced hypothermia: effects on coronary blood flow autoregulation and vascular reserve

Surface-induced hypothermia has been shown to exert a protective effect in canine models of myocardial infarction. However, its effects on coronary blood flow (CBF) autoregulation and coronary vascular reserve (CVR) have not been investigated. The effects of mild (32 degrees C) and moderate (27 degrees C) hypothermia on CBF autoregulation and CVR (at 60 mm Hg diastolic pressure) were studied using a chronically instrumented canine preparation. Coronary artery pressure-flow relations were obtained over a wide range of coronary diastolic pressures (10 to 106 mm Hg) with autoregulation intact and during adenosine-induced maximal coronary conductance (MCC) at 37, 32, 27 degrees C (n = 7 dogs), and after rewarming (n = 5 dogs). Halothane (1 MAC end-tidal concentration, temperature adjusted) was the anesthetic. Autoregulation remained intact during hypothermia. CBF remained relatively constant between diastolic pressures of 43.1 +/- 9.0 and 84.0 +/- 14.4 mm Hg (mean +/- SD). No significant differences were observed between temperatures in the autoregulated pressure range. CBF correlated well with myocardial oxygen consumption (MVO2) (r2 = 0.81, P less than 0.0001). There were no significant changes in MVO2, CBF, MCC, or CVR at 32 degrees C. At 27 degrees C, MVO2 (3.65 +/- 1.3 at 37 degrees C vs 2.35 +/- 1.4 ml O2.min-1 at 27 degrees C), autoregulated CBF (34.9 +/- 15.1 vs 19.5 +/- 10.8 ml.min-1), the slope of the line of MCC (4.31 +/- 0.7 vs 2.7 +/- 0.4 ml.mm-1.min-1), and CVR (147.1 +/- 24.6 vs 90.1 +/- 27.3 ml.min-1) were all less than control (P less than 0.05). After rewarming to 37 degrees C, no significant changes from control were noted. The authors conclude that coronary autoregulation remains intact at both 32 and 27 degrees C, although MCC and CVR are significantly decreased at 27 degrees C.     

Effectiveness of forced air warming after pediatric cardiac surgery employing hypothermic circulatory arrest without cardiopulmonary bypass

STUDY OBJECTIVE: To evaluate the effectiveness of forced-air warming compared to radiant warming in pediatric cardiac surgical patients recovering from moderate hypothermia after perfusionless deep hypothermic circulatory arrest. DESIGN: Prospective unblinded study. SETIING: Teaching hospitals. PATIENTS: 24 pediatric cardiac surgical patients. INTERVENTION: Noncyanotic patients undergoing repair of atrial or ventricular septal defects were cooled by topical application of ice and rewarmed initially in the operating room by warm saline lavage of the pleural cavities. On arrival at the intensive care unit (ICU), patients were warmed by forced air (n = 13) or radiant heat (n = 11). The time, heart rate, and blood pressure at each 0.5 degrees C increase in rectal temperature were measured until normothermia (36.5 degrees C) to determine the instantaneous rewarming rate. MEASUREMENTS AND MAIN RESULTS: Baseline characteristics were not different in the two groups. The mean (+/- SD) age was 5.6 +/- 3.4 years, weight was 20 +/- 8 kg, esophageal temperature for circulatory arrest was 25.7 +/- 1.3 degrees C, and duration of circulatory arrest was 25 +/- 11 minutes. The mean core temperature on arrival at the ICU was 29.9 +/- 1.3 degrees C and ranged from 26.1 to 31.5 degrees C. The mean rewarming rate for each 0.5 degrees C was greater (p < 0.05) for forced-air (2.43 +/- 1.14 degrees C/hr) than radiant heat (2.16 +/- 1.02 degrees C/hr). At core temperatures <33 degrees C, the rewarming rate for forced-air was 2.04 +/- 0.84 degrees C/hr and radiant heat was 1.68 +/- 0.84 degrees C/hr (p < 0.05). At core temperatures > or = 33 degrees C, the rewarming rate for forced air was 2.76 +/- 1.20 degrees C/hr and radiant heat was 2.46 +/- 1.08 degrees C/min (p = 0.07). Significant determinants of the rewarming rate in a multivariate regression model were age (p < 0.001), temperature (p < 0.05), time after arrival to the intensive care unit (p < 0.05), pulse pressure (p < 0. 05) and warming device (p < 0.001). The duration of ventilatory support and ICU length of stay was not different in the two groups. CONCLUSIONS: Both forced-air and radiant heat were effective for rewarming moderately hypothermic pediatric patients. When core temperature was less than 33 degrees C, the instantaneous rewarming rate by forced air was 21% faster than by radiant heat.     

Effect of a Cooling Vest on Core Temperature in Athletes With and Without Spinal Cord Injury

Background:

It is well accepted that persons with spinal cord injury (SCI) have impaired ability to regulate core temperature due to impaired vasomotor and sudomotor activity below their level of injury. Impaired heat dissipation puts SCI athletes at great risk of exercise-induced hyperthermia (EIH) (>37.8°C). There is minimal evidence for efficacy of any specific cooling method in SCI athletes in a thermoneutral sport-specific setting.

Objective:

To evaluate the extent of EIH in persons with and without SCI and subsequently examine the effect of a cooling vest to attenuate rise in core body temperature (T_c).

Methods:

SCI (n = 17) and able-bodied (AB; n = 19) athletes participated in a 60-minute intermittent sprinting exercise in a thermoneutral (21.1°C-23.9°C) environment. Participants were separated according to their level of injury: tetraplegia defined as above T1 (TP; n = 6), high paraplegia defined as T5 through T1 (HP; n = 5), low paraplegia defined as T6 and below (LP; n = 6), and AB (n = 19). T_c was recorded at 15-minute intervals using an ingestible thermometer pill. This protocol was completed with a cooling vest (V) and without a cooling vest (NV).

Results:

All SCI and most AB athletes experienced EIH. After 60 minutes, T_c of TP athletes was significantly increased compared to HP (P = .03) and AB athletes (P = .007). There was no significant effect of the vest on T_c over time for any group.

Conclusions:

TP athletes have the highest risk of exercise-induced hyperthermia. The cooling vest does not significantly attenuate rise in T_c in SCI or AB athletes.Key words: body temperature, hyperthermia, spinal cord injury, thermoregulationInjury to the spinal cord results in impairment of vasomotor and sudomotor function at and below the level of injury (LOI).¹ In non–spinal-cord-injured individuals, internal heat gain from metabolically active muscles (eg, during exercise) and external heat gain from the ambient air is mitigated through processes regulated by the hypothalamus. The afferent input of heat gain results in neurological efferent signals that regulate vasomotor tone (convective cooling) and sudomotor activation (evaporative cooling). In persons with spinal cord injury (SCI), the output from the hypothalamus is blocked due to lesions within the spinal cord. Furthermore, the loss of skeletal muscle pump activity from the paralyzed limbs further impairs blood circulation and thus core temperature regulation. As a result, persons with SCI have difficulty dissipating heat during exercise compared to their able-bodied (AB) counterparts.^1–3 The extent of such thermal impairment has been shown to be directly related to level and completeness of injury, with higher and complete lesions having more impairment than lower, incomplete lesions.^4,5 Specifically, the vessels of the face and neck are sympathetically mediated from levels T1-4, upper extremity vessels mediated from T5-7, and vessels of the lower extremity from T10 to L3.⁶ Therefore, persons with complete tetraplegia have essentially no vasomotor control, whereas persons with high paraplegia have vasomotor control of face and neck and persons with low paraplegia have control of upper limbs and potentially some control of lower limb vessels depending on the LOI.In the AB athlete, is it well accepted that elevated core temperature (T_c) due to internal and external heat gain during exercise can impair endurance and performance.^7,8 Extreme elevations in T_c can result in exercise-induced hyperthermia (EIH) (>37.8°C-38.3°C) that that can lead to heat exhaustion (<40°C) or heat stroke (>40°C) as defined by American College of Sports Medicine (ACSM).⁹ For this reason, cooling methods such as whole body cooling, cooling vests, and hand/foot cooling are utilized before and during exercise in AB athletes.^10–13 These devices have been shown to reduce thermal strain, increase endurance capacity, and improve performance.^14–17Due to the increased risk of EIH and heat-related illness from thermoregulatory dysfunction in persons with SCI, a number of commercially available cooling devices have been tested in a controlled laboratory setting in attempts to attenuate rise in T_c. Foot cooling garments, hand cooling garments, head and neck cooling garments, misting devices, and a cooling vest have been tested in SCI populations.^18–22 This study sought to test the efficacy of the cooling device in a sport-specific environment. The cooling vest interferes minimally with wheelchair propulsion during sporting activities and was thus chosen for this study.While the efficacy of the cooling vest in normalizing T_c in the AB population has been clearly documented, the efficacy of the vest in SCI populations has variable results from 3 small studies.^14,23,24 Armstrong et al¹⁸ found that cooling (ice) vests worn during 30 minutes of wheelchair roller exercise in a hot-humid environment (~33°C and ~75% relative humidity) did not significantly decrease T_c in an SCI group (4 with paraplegia, 1 with tetraplegia). Webborn et al evaluated the effect of cooling vests in 2 studies of 8 persons with tetraplegia during an arm crank ergometry intermittent sprint protocol (defined as 14 two-minute exercise periods each consisting of 10 seconds passive rest, 5 seconds maximum sprint, and 105 seconds of active recovery). The first study reported a significant decrease in T_c and rate of perceived exertion when vests were used before (pre-cooling) or during 28 minutes of exercise in the heat.¹⁹ The second study also reported a significant decrease in T_c and time to exhaustion during 60 minutes in the heat when wearing the vest.²⁵ Webborn recommended that tetraplegic athletes performing intermittent sprint exercise in hot conditions should wear a cooling vest before or during exercise to attenuate rise in T_c. This study tested Webborn’s recommendation to examine whether these findings translate to a nonlaboratory field-based environment of athletes engaging in intermittent sprint exercise during play of wheelchair basketball and rugby. This concept of testing has recently been recommended, as testing of athletes in their normal sports wheelchair and their natural environment may yield results that are more relevant than laboratory testing.²⁶The objectives of this study are 2-fold: (1) to evaluate the extent of EIH in persons with and without SCI, and (2) to examine the ability of a cooling vest to attenuate the rise in T_c of SCI and AB athletes during intermittent sprinting exercise.     

Auditory brainstem evoked responses and temperature monitoring during pediatric cardiopulmonary bypass

PURPOSE: To examine the effects of temperature on auditory brainstem responses (ABRs) in infants during hypothermic cardiopulmonary bypass for total circulatory arrest (TCA). The relationship between ABRs (as a surrogate measure of core-brain temperature) and body temperature as measured at several temperature monitoring sites was determined. METHODS: In a prospective, observational study, ABRs were recorded non-invasively at normothermia and at every 1 or 2 degrees C change in ear-canal temperature during cooling and rewarming in 15 infants (ages: 2 days to 14 months) that required TCA. The ABR latencies and amplitudes and the lowest temperatures at which an ABR was identified (the threshold) were measured during both cooling and rewarming. Temperatures from four standard temperature monitoring sites were simultaneously recorded. RESULTS: The latencies of ABRs increased and amplitudes decreased with cooling (P < 0.01), but rewarming reversed these effects. The ABR threshold temperature as related to each monitoring site (ear-canal, nasopharynx, esophagus and bladder) was respectively determined as 23 +/- 2.2 degrees C, 20.8 +/- 1.7 degrees C, 14.6 +/- 3.4 degrees C, and 21.5 +/- 3.8 degrees C during cooling and 21.8 +/- 1.6 degrees C, 22.4 +/- 2.0 degrees C, 27.6 +/- 3.6 degrees C, and 23.0 +/- 2.4 degrees C during rewarming. The rewarming latencies were shorter and Q10 latencies smaller than the corresponding cooling values (P < 0.01). Esophageal and bladder sites were more susceptible to temperature variations as compared with the ear-canal and nasopharynx. CONCLUSION: No temperature site reliably predicted an electrophysiological threshold. A faster latency recovery during rewarming suggests that body temperature monitoring underestimates the effects of rewarming in the core-brain. ABRs may be helpful to monitor the effects of cooling and rewarming on the core-brain during pediatric cardiopulmonary bypass.     

Posttraumatic migraine characteristics in athletes following sports-related concussion

OBJECT: The object of this study was to compare symptom status and neurocognitive functioning in athletes with no headache (non-HA group), athletes complaining of headache (HA group), and athletes with characteristics of posttraumatic migraine (PTM group). METHODS: Neurocognitive tests were undertaken by 261 high-school and collegiate athletes with a mean age of 16.36 +/- 2.6 years. Athletes were separated into three groups: the PTM group (74 athletes with a mean age of 16.39 +/- 3.06 years), the HA group (124 athletes with a mean age of 16.44 +/- 2.51 years), and the non-HA group (63 patients with a mean age of 16.14 +/- 2.18 years). Neurocognitive summary scores (outcome measures) for verbal and visual memory, visual motor speed, reaction time, and total symptom scores were collected using ImPACT, a computer software program designed to assess sports-related concussion. Significant differences existed among the three groups for all outcome measures. The PTM group demonstrated significantly greater neurocognitive deficits when compared with the HA and non-HA groups. The PTM group also exhibited the greatest amount of departure from baseline scores. CONCLUSIONS: The differences among these groups can be used as a basis to argue that PTM characteristics triggered by sports-related concussion are related to increased neurocognitive dysfunction following mild traumatic brain injury. Thus, athletes suffering a concussion accompanied by PTM should be examined in a setting that includes symptom status and neurocognitive testing to address their recovery more fully. Given the increased impairments observed in the PTM group, in this population clinicians should exercise increased caution in decisions about treatment and when the athlete should be allowed to return to play.