Salivary glands, their hormones, and thermoregulation

The effects of the removal of the submandibular glands (sialadenectomy) on the fever induced by bacterial lipopolysaccharide (LPS) were examined. Thermally sensitive radiotransmitters were implanted into the abdomens of adult male Sprague-Dawley rats that experienced at this time either a sham operation or a sialadenectomy, and one week later body temperatures were recorded by telemetry in these rats when conscious. The initial fever (up to 180 min following LPS) response, following the intraperitoneal injection of 150 micrograms/kg E. coli LPS, was similar in the two groups of rats, but the second phase of the fever (240 to 420 min post-LPS) was modestly, but significantly higher (mean = 0.26 degree C) in sialadenectomized rats. A submandibular gland peptide (compound T; 100 micrograms/kg), given one-half hour before the LPS, did not affect the early fever, but suppressed the late-phase fever by 0.37 degree C (mean). The submandibular glands, which form an integral part of the neuroendocrine mechanisms responsible for attenuating the responses of the immune system to inflammatory stimuli, also appear to modulate thermogenic responses to these stimuli.

Prostaglandin fever in rats throughout the estrous cycle late pregnancy and post parturition

We have examined the influence of natural variations in endocrine status on the ability to generate a prostaglandin-induced fever in virgin female, pregnant and lactating rats and compared responses to those in male rats. Endocrine status of virgin female rats was assessed from examination of vaginal smears and time of parturition noted to enable accurate dating of pre- and postparturient fevers. Unanesthetized rats, previously prepared with intraventricular guide cannulas and intraperitoneal telemetry thermistors, were given intraventricular injections of prostaglandin E1 (2-100 ng/5 microliters) and temperatures monitored for 3 h after injection. Virgin females developed significantly larger fevers than did males at higher doses. There were no significant alterations in either fever height or duration as a function of the phase of the reproductive cycle in the females. Both pregnant and postparturient rats within the several days around birth displayed significantly lower fevers than did virgin females, but there was no further reduction in the immediate periparturient period. These data indicate that there are sex-, and possibly hormone-dependent differences in the central mechanisms involved in fever generation and antipyresis.

Fever in pregnant, parturient, and lactating rats

Conscious virgin, pregnant, or lactating rats were given intravenous Escherichia coli endotoxin while their temperatures were monitored telemetrically. Virgin females responded to 10-50 micrograms/kg endotoxin with a slight hypothermia, followed by a fever of nearly 2 degrees C magnitude. In pregnant rats given 25 micrograms/kg of the endotoxin, fevers were reduced between 96 h before and 24 h after parturition compared with those seen in virgins or in lactating rats > 24 h postpartum. In the 24-h period before expected time of parturition, no rat developed a fever and the majority of animals became hypothermic; furthermore, in 80% of such animals given 25 micrograms/kg endotoxin, the hypothermia was accompanied by death within 3-15 h. Some mortality and hypothermia were also seen up to 48 h before birth and up to 24 h after birth. No mortality was observed in virgin, pregnant, or lactating rats outside of this time period. We conclude that, around the time of delivery, there is a suppression of fever in the rat and occasional toxic responses to endotoxin.

Effect of potassium-induced cortical spreading depression on prostaglandin-induced fever in conscious and urethane-anesthetized rats

Potassium-induced cortical spreading depression (CSD) on prostaglandin E1 (PGE1) induced fever has been investigated in a dose-responsive experimental design in both conscious and urethane-anesthetized adult male Sprague-Dawley rats. While CSD in itself had no effect on nonfebrile body temperature even under cold ambient conditions, CSD significantly suppressed small but not large fevers induced by intracerebroventricular PGE1. The increased oxygen consumption during fever was also reduced. We also explored the possible involvement of the antipyretic peptide arginine vasopressin, in the CSD-induced suppression of fever. Long term castrated rats have significantly reduced ventral septal levels of this peptide, yet CSD was effective in suppressing the initial 40 min of PGE1 fever in these animals. Thus we conclude that increased release of ventral septal arginine vasopressin is probably not involved in the action of CSD on fever.

A method for continuous blood sampling during cold water immersion

A technique, consisting of a pre-calibrated, catheter-peristaltic pump combination, for continuous blood sampling was tested using six volunteers during a 20 min immersion in cold water at 14.7 +/- 0.9 degrees C. The device offered the advantage of continued collection of blood samples from an antecubital vein during the experiment with little discomfort for the subjects and in sufficient volume for assay of plasma constituents eg. catecholamines.

Vasopressin perfusion within the medial amygdaloid nucleus attenuates prostaglandin fever in the urethane-anaesthetized rat

The antipyretic effect of arginine vasopressin (AVP) introduced into the ventral septal area (VSA) by push-pull perfusion was investigated in the urethane-anaesthetized rat. In addition, experiments were carried out to determine whether AVP could suppress fever when similarly perfused within the medial amygdaloid nucleus (meA). During push-pull perfusion of artificial cerebrospinal fluid within the VSA or meA, PGE1 injected intracerebroventricularly evoked fevers with respective magnitudes of 1.3 +/- 0.2 degrees C and 1.4 +/- 0.3 degrees C above baseline. Perfusion of AVP (6.5 micrograms/ml) within the VSA had significantly reduced the magnitude of PGE1 fever to 0.3 +/- 0.3 degrees C above baseline, while having no significant effect on afebrile colonic temperature. Perfusion of AVP (6.5 micrograms/ml) within the meA had significantly attenuated the magnitude of PGE1 fever to 0.7 +/- 0.2 degrees C above baseline, while having no significant effect on afebrile colonic temperature. These results support further the utility of the urethane-anaesthetized rat model for future investigations of the central control of fever and antipyresis. In addition, these data are consistent with the hypothesis that AVP may act within the meA as an endogenous antipyretic.

Vasopressin and oxytocin in rat brain in response to prostaglandin fever

Urethan-anesthetized rats were used to identify effective stimuli for the release of the peptides arginine vasopressin (AVP) and oxytocin into the ventral septal area (VSA) of the brain. Febrile responses to intracerebroventricular injection of prostaglandin E1 (PGE1) were observed in rats whose body temperatures were maintained at 35, 37, or 39 degrees C. Microinjection of the AVP antagonist d(CH2)5Tyr(Me)AVP into the VSA enhanced fever only when PGE1 administration was associated with a significant rise in body temperature. Passive elevation ("artificial fever") or reduction of body temperature in the absence of a PGE1 stimulus was not affected by the antagonist. Push-pull perfusion of the VSA and the dorsal hippocampus, followed by radioimmunoassay of perfusates for AVP and oxytocin, revealed enhanced release into the VSA of AVP only when PGE1 administration was followed by a rise in body temperature. Oxytocin was released whenever body temperature was raised. Peptide concentrations in simultaneous perfusates of dorsal hippocampus did not change in response to PGE1 administration or to passive elevation of body temperature. We conclude that AVP is released into the VSA, but not the dorsal hippocampus, of the rat during a fever induced by PGE1. Oxytocin is released into the VSA, but not the hippocampus, when temperature is elevated.

Depletion of brain alpha-MSH alters prostaglandin and interleukin fever in rats

Alpha-melanocyte stimulating hormone (alpha-MSH), a putative endogenous antipyretic agent, is synthesized largely within neurons in the arcuate nucleus. To test the hypothesis that destruction of this area would increase the febrile response, male Wistar rats, treated as neonates with intraperitoneal injections of monosodium glutamate (MSG) or saline, were given intracerebroventricular (i.c.v.) injections of prostaglandin E1 (20 ng; 200 ng) or purified interleukin-1 (20 U) and body temperature was monitored. The fevers displayed by the MSG-treated animals were significantly greater (P less than 0.05) than those of the controls for the lower dose of PGE1 at 10-30 min and for IL-1 at 3-6 h after the injections. MSG-treated rats showed significant reduction (P less than 0.01) in alpha-MSH content of the medial basal hypothalamus and lateral septum when compared to saline controls. Body temperature response of non-febrile animals to high ambient temperature was not affected by the MSG treatment. These data support the hypothesis that alpha-MSH is an endogenous antipyretic in the rat.

Cerebrospinal fluid pressure in conscious rats during prostaglandin E1 fever

Intraperitoneal body temperature was monitored from groups of 10 conscious adult male Wistar rats. The daily body temperature rhythm was determined, and an intraperitoneal body temperature dose response relationship was established for prostaglandin E1 (PGE1) delivered into a lateral cerebral ventricle (LCV). Cerebrospinal fluid pressure was measured by direct cannulation of a LCV. Heart rate, arterial and central venous blood pressure, and blood gases were also measured in groups of 10 animals. It was found that there was a daily rhythm in intraperitoneal body temperature that was higher at night than during the day but stable between 0800 and 1600 h. A significant temperature dose (20-2,000 ng)-response relationship was established for administration of PGE1 into the LCV. Cerebrospinal fluid pressure when measured from the LCV increased significantly during the "chill" phase of the PGE1-induced fever. Carotid arterial blood pressure also significantly increased at this time as did central venous pressure, particularly so with vigorous shivering. There was a significant fall in arterial CO2 partial pressure, a slight rise in pH, and no change in arterial O2 partial pressure. These data support the hypothesis that a significant increase in cerebrospinal fluid pressure occurs during the chill phase of a PGE1-induced fever in the conscious rat.

Acute changes in forearm venous volume and tone using radionuclide plethysmography

In this investigation blood pool scintigraphy was validated as a method to study acute changes in human forearm veins. Changes in regional forearm vascular volume (capacity) and the occluding pressure-volume (P-V) relationship induced by sublingual nifedipine (NIF) and nitroglycerin (GTN) were recorded in 16 patients with simultaneous data collection by the radionuclide and the mercury-in-rubber strain-gauge techniques. The standard error of estimate (Syx) between successive control measurements using the radionuclide method was 3.1% compared with 3.2% for the strain-gauge method. The venous P-V curves were highly reproducible using both techniques. Strain gauge and radionuclide measurements of acute changes in forearm venous volume correlated well (r = 0.86; Syx = 7%, n = 156). After 20 mg of NIF or 0.6 mg of GTN, mean heart rate increased from 71 +/- 10 to 77 +/- 9 and from 68 +/- 10 to 75 +/- 11 beats/min, respectively, and group systolic blood pressure decreased from 128 +/- 22 to 120 +/- 19 and from 136 +/- 18 to 126 +/- 23 mmHg, respectively (P less than 0.05). At venous occluding pressures of 0 and 30 mmHg, the forearm vascular volume did not change after NIF (2 +/- 4 and -1 +/- 4%; P greater than 0.05), whereas it increased after GTN (8 +/- 5 and 12 +/- 7%; P less than 0.001). The forearm venous P-V relationship did not change after NIF, whereas a significant rightward shift (venodilation, with an increase in unstressed volume) occurred after GTN.(ABSTRACT TRUNCATED AT 250 WORDS)

Plasma catecholamines in conscious rabbits after central administration of vasopressin

Arterial levels of epinephrine (E) were significantly raised for all times sampled, after intracerebroventricular (i.c.v.) injection of arginine vasopressin (AVP) (1 nmol) into conscious rabbits. Venous levels of norepinephrine (NE) were significantly raised within the first 4 min after a similar i.c.v. injection of AVP. The significant increases in arterial E and venous NE correspond in time and therefore could account for changes in heart rate and blood pressure elicited by centrally injected AVP. Therefore, AVP could influence cardiovascular function by increasing the activity of the sympatho-adrenomedullary system.

Changes in body temperature and vasopressin content of brain neurons, in pregnant and non-pregnant guinea pigs, during fevers produced by Poly I:Poly C

The synthetic polyribonucleotide pyrogen Poly I:Poly C (800 micrograms.kg-1) was injected intramuscularly on alternate days into pregnant and non-pregnant female guinea pigs. Pregnant animals, close to term, had smaller fevers in response to the pyrogen than did non-pregnant animals. Repeated injections of the pyrogen caused sequentially smaller fevers for the first 3-4 injections, particularly in non-pregnant animals, and this appeared to be like the tolerance usually developed to repeated injections of endotoxin. Continued pyrogen injections then caused, in non-pregnant animals, fevers of increasing magnitude until the original fever levels were reached, whereas in pregnant guinea pigs the fever responses remained reduced until parturition. The development of tolerance was associated with an increase in immunoreactivity for arginine vasopressin (AVP) in some neurons in the medial part of the paraventricular nucleus, and in terminals in the lateral septum and amygdala similar to changes found in these areas at term of pregnancy. These observations raise the possibility that AVP in these regions may have a role in the development of tolerance to pyrogens, and further quantitative studies of the AVP content of, and release from, nerve terminals projecting to the limbic system seem warranted.

Prostaglandin fever in rats is altered by kainic acid lesions of the ventral septal area

The ventral septal area (VSA) has been shown to be a region within the rat brain where arginine vasopressin (AVP) acts to reduce fever. To test the hypothesis that destruction of this area would affect the magnitude of the febrile response, body temperature was monitored in male, Wistar rats given intracerebroventricular injections of prostaglandin E1 (200 ng) and saline (10 microliter) before and after bilateral injections of kainic acid (KA) or of saline vehicle into the VSA. While fever heights were unaffected by the lesion, fever in the KA-lesioned animals remained significantly elevated (P less than 0.05) for 1 h after the peak response. There was no significant difference in the fever responses displayed by sham-lesioned animals. The body temperature response of non-febrile animals to high or low ambient temperature was unaffected by the lesions. The enhanced fever following the KA lesion, but not sham lesions of the VSA would support the hypothesis that this region is involved in endogenous suppression of fever.

Physiological changes during thermoregulation and fever in urethan-anesthetized rats

Adult male Wistar rats were anesthetized with urethan (1.5 g/kg). They were unable to maintain body temperature (Tb) in a warm (32 degrees C) or cool (9 degrees C) environment or at a laboratory room temperature of 22 degrees C. Tb was allowed to fall to 35.8, 34.5, or 33.3 degrees C, and prostaglandin E1 (PGE1, 400 ng) was delivered into a lateral cerebral ventricle. An immediate feverlike rise in Tb resulted, accompanied by vigorous shivering. Animals were vasoconstricted throughout. When Tb was raised to and maintained at 38.3 or 39.5 degrees C, animals also responded with a fever; however, the magnitude of the fever diminished as the starting Tb increased. In a series of experiments in which Tb was maintained (36.8-37.4 degrees C) by means of a heating pad, PGE1 delivered into a lateral cerebral ventricle or into the anterior hypothalamus caused a dose-dependent change in Tb, which was similar in time of onset, magnitude, and duration to that observed in conscious animals. This fever was accompanied by shivering and increased O2 uptake, heart rate, arterial blood pressure, respiratory rate, and intracranial pressure during the rising phase of the fever, and vasodilation of the paws occurred during defeveresence. Animals were also able to develop a dose-dependent rise in Tb in response to purified human interleukin 1.

The role of vasopressin as an antipyretic in the ventral septal area and its possible involvement in convulsive disorders

Perfusion of the peptide, arginine vasopressin (AVP), within the ventral septal area (VSA) of the brain of a number of species reduces fever but not normal body temperature. This antipyretic response appears to be mediated by AVP receptors of the V1 subtype. Lesions of the VSA with kainic acid are associated with prolonged and enhanced fevers in rats. A role for endogenous AVP in fever suppression within the VSA comes from several types of experiments: (1) AVP release within the VSA is inversely correlated to fever height; (2) AVP antagonists or antiserum injected into the VSA prolong fever; (3) animals lacking endogenous AVP in the VSA (Brattleboro rat, long-term castrated rat) develop enhanced fevers. Electrical stimulation of the AVP-containing cell bodies of the bed nucleus of the stria terminalis (BST) orthodromically inhibits VSA neurons and also suppresses fever; the latter effect can be abolished with application of a V1 antagonist to the VSA. Iontophoretic studies indicate that AVP inhibits glutamate-stimulated activity of thermoresponsive and other VSA neurons. AVP can also act in the VSA to cause severe motor disturbances; this action is receptor mediated and increases in severity upon sequential exposure to AVP. Because sites of action of the antipyretic and convulsive action of AVP are similar, and because animals lacking brain AVP display reduced convulsive activity, it is possible that AVP, released during fever, could be involved in the genesis of convulsive activity.

Enhanced fever following castration: possible involvement of brain arginine vasopressin

Arginine vasopressin (AVP) is thought to act as an antipyretic in the ventral-septal area (VSA) of the brain. As AVP content of this area has been shown to be virtually eliminated following long-term castration, we have tested the hypothesis that castrated rats would display enhanced fevers. Four months after castration (or sham castration), male Wistar rats were given prostaglandin E1 (200 ng), purified interleukin 1 (25 U), or saline (5 microliters) into a lateral cerebral ventricle. Castrated rats displayed fevers of longer duration, reflected as significantly enhanced thermal indexes, than did age-matched sham-operated controls. Castrated rats also were less able to defend their body temperatures to ambient heat stress but not to ambient cold. AVP content of VSA and lateral septum, but not of hippocampus, of castrated rats was significantly reduced; oxytocin content of the three areas was unchanged following castration. These data support earlier studies concerning effects of castration on septal AVP content and are consistent with the possibility that AVP is an antipyretic in the VSA of the rat.

Perfusion of the septum of the rabbit with vasopressin antiserum enhances endotoxin fever

The septal region of the brains of conscious, adult, male New Zealand White rabbits were perfused by means of a push-pull system before and after an intravenous administration of bacterial pyrogen extracted from Salmonella abortus equi. Perfusion of the septal area with sucrose solution (260 mM) had no significant effect on the resulting fever (1.13 +/- 0.09 degrees C) when compared to a control fever without the push-pull perfusion (1.06 +/- 0.12 degrees C). Arginine vasopressin (AVP) added to the perfusing solution (20 micrograms/ml) caused a significant attenuation of the fever (0.81 +/- 0.20 degrees C). An antiserum specific to AVP when added to the perfusing solution resulted in a fever which was significantly greater (2.38 +/- 0.13 degrees C) than the control. Radioimmunoassay of perfusates collected from the control perfusions before and during fever showed that, as the body temperature rose in response to the pyrogen, the level of AVP in the perfusate collected from the septal area decreased. These results provide further evidence that AVP may act in the septal area of the brain to modulate the febrile response.

The action of centrally administered arginine vasopressin on blood pressure in the conscious rabbit

In addition to its peripheral endocrine actions, arginine vasopressin (AVP) has been implicated in the central control of blood pressure. Intracerebroventricular (i.c.v.) injections (0.01-1.0 nmol) of AVP or arginine vasotocin (AVT), but not oxytocin (OXY), into unanesthetized rabbits caused a rapid, dose related rise in blood pressure as well as increases in heart rate. The lowest centrally administered dose of AVP and AVT (0.01 nmol) had no effect on blood pressure when given intravenously. In search of tissue locus for the pressor effect of AVP microinjection of AVP and OXY into the posterior hypothalamus and septum of conscious rabbits was without effect. However, microinjection (0.01-0.04 nmol) of AVP into the nucleus tractus solitarius of anesthetized rabbits caused a rise in blood pressure similar to the response seen after i.c.v. injection. Comparable volumes of the vehicle into the ventricle or the tissue sites had no effect on resting blood pressure. The pressor response after AVP given i.c.v. was significantly reduced up to 3 h after administration of the ganglionic blocker, chlorisondamine HCl. The central antagonist, d(CH2)5Tyr (Me) vasopressin, eliminated the usual increase in blood pressure after administration of AVP in half the animals tested. The results indicate that AVP acts centrally to mediate cardiovascular responses in unanesthetized as well as anesthetized rabbits.

Induced changes in intracranial pressure in the anesthetized rat and rabbit

Intracranial pressure (ICP) was measured continuously in anesthetized, free-breathing, adult, male Sprague-Dawley rats and New Zealand White rabbits by means of a subarachnoid screw technique. The effect upon ICP of changing the volumes within the cranium by infusion of artificial cerebrospinal fluid into the lateral cerebral ventricle at various rates was examined. Results obtained demonstrated some of the elastic and compensatory aspects of cerebrospinal fluid dynamics. The effects upon ICP of the intravenous administration of urea, mannitol, acetazolamide, dimethyl sulfoxide, norepinephrine, epinephrine, isoproterenol, nitroglycerin, papaverine, histamine, angiotension II, pitressin, sodium nitroprusside, diazoxide, lidocaine, sodium pentobarbitone, as well as inhalation of amyl nitrate and carbon dioxide were examined in anesthetized rats. The effect upon ICP of the intravenous infusion of urea, as well as the bolus intravenous administration of epinephrine and pitressin was examined in the anesthetized rabbit. Results obtained from these animals demonstrate the action of these experimental interventions upon ICP as measured by means of the subarachnoid screw technique.

Fever and intracranial pressures

The effect of fever upon intracranial pressures was determined in the rabbit and cat. In the unanesthetized rabbit and cat, cerebrospinal fluid (CSF) pressure was measured via direct cannulation of the lateral cerebral ventricle. Intracranial pressure (ICP) was measured in the rabbit by a subarachnoid screw technique. In all cases, intravenous administration of bacterial pyrogen extracted from Salmonella abortus equi resulted in significant differences from controls in physiological variables measured during the initial "chill" phase of the fever. There was an increase in body temperature, a fall in CSF or ICP pulse rate, an increase in pulse pressure amplitude, and a small increase in mean CSF or ICP. In addition, venous and arterial blood pressures increased significantly and, consistent with heat conservation, there was a fall in respiratory rate as well as cutaneous vasoconstriction in the ears. The arterial carbon dioxide tension was unchanged during the prodrome but fell significantly during the chill and flush phases and rose again during defervescence. The results suggest that in these animals there is a slight increase in pressures within the cranium during the "chill" phase of a pyrogen induced fever, resulting from changes occurring in many body systems during this phase of the fever.

Peripheral blood flow during rewarming from mild hypothermia in humans

During the initial stages of rewarming from hypothermia, there is a continued cooling of the core, or after-drop in temperature, that has been attributed to the return of cold blood due to peripheral vasodilatation, thus causing a further decrease of deep body temperature. To examine this possibility more carefully, subjects were immersed in cold water (17 degrees C), and then rewarmed from a mildly hypothermic state in a warm bath (40 degrees C). Measurements of hand blood flow were made by calorimetry and of forearm, calf, and foot blood flows by straingauge venous occlusion plethysmography at rest (Ta = 22 degrees C) and during rewarming. There was a small increase in skin blood flow during the falling phase of core temperature upon rewarming in the warm bath, but none in foot blood flow upon rewarming at room air, suggesting that skin blood flow seems to contribute to the after-drop, but only minimally. Limb blood flow changes during this phase suggest that a small muscle blood flow could also have contributed to the after-drop. It was concluded that the after-drop of core temperature during rewarming from mild hypothermia does not result from a large vasodilatation in the superficial parts of the periphery, as postulated. The possible contribution of mechanisms of heat conduction, heat convection, and cessation of shivering thermogenesis were discussed.

Histologic reaction to a new microsurgical suture in rabbit reproductive tissue

A newly introduced coated polyglactin suture was compared with a polyglycolic acid suture following microsurgical repair of standard rabbit uterine incisions. The degree of inflammatory response and tissue fibrosis for each suture was scored, and the results were compared. At 30 days, an inflammatory response was noted in both groups, with a greater response noted in the polyglycolic acid group. At 90 days, the inflammatory response and tissue fibrosis at the site of repair was evident in both groups, with no significant difference between the groups. The previously reported difference between these two absorbable suture materials in their earlier formulations could not be demonstrated in rabbit reproductive tissue. If an absorbable suture is used for tubal surgery, the choice can be made on considerations other than tissue reactivity.

Expired air volumes of males and females during cold water immersion

Expired air volumes were measured from a random population of adult male and female human volunteers before and during short-term immersion in either cold (13.53 +/- 0.13 degrees C) or warm (33.18 +/- 0.11 degrees C) water. A statistically significant difference was found in the pulmonary ventilation over the first 4 min of immersion between males and females when immersed in cold water. The swim suits worn could not account for the differences observed. No statistically significant difference in pulmonary ventilation was found between males and females during warm water immersion. A numerically smaller group of volunteers was preheated in a sauna before immersion in cold or warm water and this resulted in an attenuated ventilatory response. In this instance there is no statistically significant difference in ventilation between males and females. Also, in another small group of volunteers, surface and deep skin temperatures were continuously measured before and during immersion in cold water. The rates of change of deep skin temperature between males and females were found to be similar.

Measurement of intracranial pressure in the unanesthetized rabbit

A method is described for the measurement of intracranial pressure in the unanesthetized, minimally restrained rabbit utilizing a modified subarachnoid screw system. The pressures are transmitted from within the cranium via a flexible saline filled catheter to a fixed external pressure transducer. An index of the relative vertical position of the animal's skull as compared to the fixed transducer is given by means of a second open-ended pressure measuring catheter, the open end of which is fixed to the subarachnoid screw assembly on the animal's skull. The system was found to be a reliable method of measurement of intracranial pressures in the minimally restrained rabbit, and could easily be adapted to other animal species. The method is currently being used to assess the effects of fever on intracranial pressures.

A simple multi-purpose cannula system for access to the brain and/or systemic vascular system of unanesthetized animals

By utilizing a pedestal system mounted on the skull containing a cerebral guide cannula with hub, and a vascular catheter which is exteriorized within the pedestal, an easily made, multi-purpose system has been developed using materials which are available from any scientific or medical supplier. This technique is adaptable for use in a wide variety of animal species and can be used in unanesthetized or anesthetized preparations.