Thermoafferent systems and their adaptive modifications

In Shackleton's trails: Central and local thermoadaptive modifications to cold and hypoxia after a man-hauling expedition on the Antarctic Plateau

Cold and hypoxia constitute the main environmental stressors encountered on the Antarctic Plateau. Hence, we examined whether central and/or peripheral acclimatisation to the combined stressors of cold and hypoxia would be developed in four men following an 11-day man-hauling expedition on this polar region. Before and after the journey, participants performed a static whole-body immersion in 21 °C water, during which they were breathing a hypoxic gas (partial pressure of inspired O₂: ~97 mmHg). To evaluate their local responses to cold, participants also immersed the hand into 8 °C water for 30 min, while they were whole-body immersed and mildly hypothermic [i.e. 0.5 °C fall in rectal temperature (T_rec) from individual pre-immersion values]. T_rec and skin temperature (T_sk), skin blood flux, and oxygen uptake (reflecting shivering thermogenesis) were monitored throughout. The polar expedition accelerated by ~14 min the drop in T_rec [final mean (95% confidence interval) changes in T_rec: Before = -0.94 (0.15) °C, After: - 1.17 (0.23) °C]. The shivering onset threshold [Before: 19 (22) min, After: 25 (19) min] and gain [Before: - 4.19 (3.95) mL min^-1 kg^-1, After: - 1.70 (1.21) mL min^-1 kg^-1] were suppressed by the expedition. T_sk did not differ between trials. The development of a greater post-expedition hypothermic state did not compromise finger circulation during the hand-cooling phase. Present findings indicate therefore that a hypothermic pattern of cold acclimatisation, as investigated in hypoxia, was developed following a short-term expedition on the South Polar Plateau; an adaptive response that is characterised mainly by suppressed shivering thermogenesis, and partly by blunted cutaneous vasoconstriction.

Habituation of the metabolic and ventilatory responses to cold-water immersion in humans

An experiment was undertaken to answer long-standing questions concerning the nature of metabolic habituation in repeatedly cooled humans. It was hypothesised that repeated skin and deep-body cooling would produce such a habituation that would be specific to the magnitude of the cooling experienced, and that skin cooling alone would dampen the cold-shock but not the metabolic response to cold-water immersion. Twenty-one male participants were divided into three groups, each of which completed two experimental immersions in 12°C water, lasting until either rectal temperature fell to 35°C or 90min had elapsed. Between these two immersions, the control group avoided cold exposures, whilst two experimental groups completed five additional immersions (12°C). One experimental group repeatedly immersed for 45min in average, resulting in deep-body (1.18°C) and skin temperature reductions. The immersions in the second experimental group were designed to result only in skin temperature reductions, and lasted only 5min. Only the deep-body cooling group displayed a significantly blunted metabolic response during the second experimental immersion until rectal temperature decreased by 1.18°C, but no habituation was observed when they were cooled further. The skin cooling group showed a significant habituation in the ventilatory response during the initial 5min of the second experimental immersion, but no alteration in the metabolic response. It is concluded that repeated falls of skin and deep-body temperature can habituate the metabolic response, which shows tissue temperature specificity. However, skin temperature cooling only will lower the cold-shock response, but appears not to elicit an alteration in the metabolic response.

Individualized and time-variant model for the functional link between thermoregulation and sleep onset

This study makes use of control system model identification techniques to examine the relationship between thermoregulation and sleep regulation. Specifically, data-based mechanistic (DBM) modelling is used to formulate and experimentally test the hypothesis, put forth by Gilbert et al., that there exists a connection between distal heat loss and sleepiness. Six healthy sleepers each spent three nights and the following day in the sleep laboratory: an adaptation, a cognitive arousal and a neutral testing day. In the cognitive arousal condition, a visit of a television camera crew took place and subjects were asked to be interviewed. During each of the three 25-min driving simulator tasks per day, the distal-to-proximal gradient and the electroencephalogram are recorded. It is observed from these experimental data that there exists a feedback connection between thermoregulation and sleep. In addition to providing experimental evidence in support of the Gilbert et al. (2004) hypothesis, the authors propose that the nature of the feedback connection is determined by the nature of sleep/wake state (i.e. NREM sleep versus unwanted sleepiness in active subjects). Besides this, an individualized and time-variant model for the linkage between thermoregulation and sleep onset is presented. This compact model feeds on real-time data regarding distal heat loss and sleepiness and contains a physically meaningful parameter that delivers an individual- and time-depending quantification of a well known biological features in the field of thermoregulation: the thermoregulatory error signal T(hypo)(t)-T(set)(t). A validation of these physical/biological features emphasizes the reliability and power of DBM in describing individual differences related to the sleep process.

Involvement of somatodendritic 5-HT(1A) receptors in Delta(9)-tetrahydrocannabinol-induced hypothermia in the rat

Previously, it has been reported that modulating serotonergic neurones by use of selective serotonin reuptake inhibitors (SSRI) can alter the hypothermic response produced by Delta(9)-tetrahydrocannabinol (Delta(9)-THC). The aim of the present study was to investigate the effect that activation or antagonism of 5-hydroxytryptamine (5-HT(1A)) receptors has on Delta(9)-THC-induced hypothermia. Delta(9)-THC (0.5, 2 and 5 mg/kg iv) decreased body temperature in a dose-related manner. Whilst having no significant effect on body temperature when administered 40 min prior to vehicle injection, the 5-HT(1A) receptor antagonist N-[2-[4-(2-methoxyphenyl)-1-piperazinyl]ethyl]-N-(2-pyridinyl) cyclohexanecarboxamide trihydrochloride (WAY 100635; 1 mg/kg sc) significantly potentiated the hypothermia produced by 2 and 5 mg/kg Delta(9)-THC. In order to investigate whether this effect was due to antagonism at somatodendritic autoreceptors in midbrain raphe nuclei, WAY 100635 or the 5-HT(1A) agonist 8-hydroxy-(di-n-propylamino) tetralin (8-OH-DPAT) was microinjected into either the median raphe nuclei (MRN) or dorsal raphe nuclei (DRN) 40 min prior to Delta(9)-THC injection. Following microinjection into the DRN, neither WAY 100635 (0.5 nmol/0.5 microl/10 s) nor 8-OH-DPAT (15.2 nmol/0.5 microl/10 s) had any significant effect on Delta(9)-THC-induced hypothermia. However, WAY 100635 when microinjected into the MRN significantly potentiated Delta(9)-THC-induced hypothermia, and 8-OH-DPAT microinjected into the MRN significantly inhibited Delta(9)-THC-induced hypothermia. It is suggested from these studies that the potentiation of Delta(9)-THC-induced hypothermia by WAY 100635 when administered peripherally is mainly due to antagonism at somatodendritic 5-HT(1A) autoreceptors in the MRN.

8-OH-DPAT-sensitive neurons in the nucleus raphe magnus modulate thermoregulatory output in rats

The nucleus raphe magnus (NRM) is purported to be a relay through which peripheral thermoafferent information is transmitted to thermointegrative centers located in the preoptic/anterior hypothalamus (POAH). Therefore, suppression of neural activity in the NRM should reduce thermoregulatory responses to peripheral thermal challenges, but not affect responses elicited by manipulation of POAH temperature. At low ambient temperatures lidocaine injections into the NRM of nonanesthetized rats resulted in decreases in POAH temperature, oxygen consumption, and electromyographic activity. At a warm ambient temperature, lidocaine injections into the NRM decreased the elevations in oxygen consumption and electromyographic activity elicited by cooling the POAH. The effects of lidocaine injections were duplicated by injection of a 5-HT(1A) agonist 8-hydroxy-dipropylaminotetralin (8-OH-DPAT) into the NRM. The effect of 8-OH-DPAT was eliminated by pre-treatment with a selective autoreceptor antagonist. These results suggest that NRM 5-HT neurons are modulating the relationship between output of thermointegrative centers and thermoregulatory effector responses rather than processing thermoafferent information.

Spinal neuronal thermosensitivity in vivo and in vitro in relation to hypothalamic neuronal thermosensitivity

In the spinal cord, temperature signals are generated which serve as specific inputs in the central nervous control of body temperature. Because of the spatially distinct organization of afferent and efferent neuronal systems at the spinal level, the afferent pathway for temperature signal transmission could be identified in vivo in the ascending, anterior and lateral tracts with a relationship of about 75:25% between warm and cold sensitive neuraxons. Analysis of spinal neuronal thermosensitivity in vitro on spinal cord tissue slices has been concerned, so far, with the superficial laminae of the dorsal horn as the site of origin of ascending nerve fibers conveying mostly temperature and pain signals, and with lamina X as a site of origin of afferent as well as efferent neurons. A relationship of about 95:5% between warm and cold sensitive neurons was found at the segmental level, indicating that warm sensitivity is the prevailing, primary property of spinal neurons, whereas cold sensitivity seems to be mainly generated by synaptic interaction as a secondary modality. Dynamic responses to temperature changes were frequently displayed in vitro at the spinal segmental level in lamina I + II but not in lamina X, even by neurons whose static activity was little influenced by local temperature. Dynamic thermosensitivity was found less frequently in ascending tract neuraxons and was not observed in hypothalamic neurons receiving temperature signal inputs from the spinal cord, and thus, does not seem to be relevant for the thermosensory function of spinal cord neurons, unlike peripheral warm and cold receptors. A majority of spinal warm sensitive neurons displayed both static and dynamic warm sensitivity as an inherent property after synaptic blockade. In the further analysis of spinal cord thermosensitivity, the in vitro approach permits application of the same electrophysiological and neuropharmacological methods as were established for the analysis of hypothalamic thermosensitivity. In addition, the topography of the spinal cord will provide additional structural and possibly histochemical information to characterize the functions of neurons independently of their thermal properties.

Afferent projections to the rat nuclei raphe magnus, raphe pallidus and reticularis gigantocellularis pars alpha demonstrated by iontophoretic application of choleratoxin (subunit b)

The aim of the present study was to identify the specific afferent projections to the rostral and caudal nucleus raphe magnus, the gigantocellular reticular nucleus pars alpha and the rostral nucleus raphe pallidus. For this purpose, small iontophoretic injections of the sensitive retrograde tracer choleratoxin (subunit b) were made in each of these structures. In agreement with previous retrograde studies, after all injection sites, a substantial to large number of labeled neurons were observed in the dorsal hypothalamic area and dorsolateral and ventrolateral parts of the periaqueductal gray, and a small to moderate number were found in the lateral preoptic area, bed nucleus of the stria terminalis, paraventricular hypothalamic nucleus, central nucleus of the amygdala, lateral hypothalamic area, parafascicular area, parabrachial nuclei, subcoeruleus area and parvocellular reticular nucleus. In addition, depending on the nucleus injected, we observed a variable number of retrogradely labeled cells in other regions. After injections in the rostral nucleus raphe magnus, a large number of labeled cells were seen in the prelimbic, infralimbic, medial and lateral precentral cortices and the dorsal part of the periaqueductal gray. In contrast, after injections in the other nuclei, fewer cells were localized in these structures. Following raphe pallidus injections, a substantial to large number of labeled cells were observed in the medial preoptic area, median preoptic nucleus, ventromedial part of the periaqueductal gray, Kölliker-Fuse and lateral paragigantocellular reticular nuclei. Following injections in the other areas, a small to moderate number of cells appeared. After gigantocellular reticular pars alpha injections, a very large and substantial number of labeled neurons were found in the deep mesencephalic reticular formation and oral pontine reticular nucleus, respectively. After the other injections, fewer cells were seen. Following rostral raphe magnus or raphe pallidus injections, a substantial number of labeled cells were observed in the insular and perirhinal cortices. Following caudal raphe magnus or gigantocellular reticular pars alpha injections, fewer cells were found. After raphe magnus or gigantocellular reticular pars alpha injections, a moderate to substantial number of cells were localized in the fields of Forel, lateral habenular nucleus and ventral caudal pontine reticular nucleus. Following raphe pallidus injections, only a small number of cells were seen. Our data indicate that the rostral and caudal parts of the nucleus raphe magnus, the gigantocellular reticular nucleus pars alpha and the nucleus raphe pallidus receive afferents of comparable strength from a large number of structures. In addition, a number of other afferents give rise to stronger inputs to one or two of the four nuclei studied. Such differential inputs might be directed to populations of neurons with different physiological roles previously recorded specifically in these nuclei.

Forebrain projections of the rostral nucleus raphe magnus shown by iontophoretic application of choleratoxin b in rats

The nucleus raphe magnus belongs to the thermoafferent system. Following iontophoretic choleratoxin b injections in its rostral part, a substantial to large number of anterogradely labeled varicose fibres were observed in the medial and lateral preoptic areas, the bed nucleus, the substantia innominata, the ventral pallidum, the median preoptic nucleus, the paraventricular hypothalamic nucleus, the central amygdaloid nucleus and the lateral and dorsal hypothalamic areas. A small to moderate number were seen in the septal nuclei, the diagonal band, the magnocellular preoptic nucleus, the anterior hypothalamic area and the paraventricular and intralaminar thalamic nuclei. After choleratoxin b injections in the preoptic, dorsal and lateral hypothalamic areas, a substantial number of retrogradely labeled serotonin immunonegative neurones were specifically found in the rostral nucleus raphe magnus. Thus, non-serotonergic rostral nucleus raphe magnus cells might directly modulate hypothalamic thermointegrative neurones.

Stress-induced changes of extracellular 5-hydroxyindoleacetic acid concentrations followed in the nucleus raphe dorsalis and the frontal cortex of the rat

In the present paper, the effect of different stressors on extracellular 5-hydroxyindoleacetic acid (5-HIAA) concentrations in the frontal cortex and the N. raphe dorsalis (NRD) of the rat were studied. The following stressful procedures were used: Immobilization, 10 min, cold, 20 min, and forced exercise in a rotating wheel, 2h. These procedures were compared with a handling procedure, 10 min. The extracellular 5-HIAA concentration was followed by in vivo voltammetry with carbon multifibre electrodes in the awake animal. Handling had no significant effect on extracellular 5-HIAA concentrations neither in the frontal cortex nor the NRD, whereas immobilization and cold evoked significant increases in both brain areas. During and after forced exercise a significant increase was measurable only in the frontal cortex, while extracellular 5-HIAA concentrations were unchanged in the NRD. Since it is very likely that the modulation of the activity of the central serotoninergic system under stressful conditions is closely connected with changes in behaviour and temperature regulation, we compared our findings on extracellular 5-HIAA levels during stress with the effect of the 5-HT1A agonist (+)-8-hydroxy-2-(di-n-propylamino)tetraline (8-OH-DPAT), a substance known to reduce body temperature. The i.p. injection of a low dose decrease significantly both, the extracellular 5-HIAA concentration in the NRD and body temperature. Our results suggest that the serotoninergic activation in the frontal cortex may prove to be a general response to stress which could function perhaps as a part of the central coping mechanism, whereas serotonin (5-HT) in the NRD may modulate specific regulatory responses such as body temperature.

The effect of prazosin pretreatment on hyperthermia produced by noradrenaline in rabbits

1. Hyperthermia produced by noradrenaline (NA) was accompanied by increased metabolic rate and vasoconstriction of ear skin vessels and a fall in evaporation heat loss. 2. Prazosin (PRA), administered as a single injection, decreased of hyperthermia elicited by NA mainly of attenuation the processes concerned with the heat production and increased of heat loss from respiratory tract and ear skin surface. 3. PRA administered in a 3 hr infusion did not only produce an abolishment of NA-induced hyperthermia but also exerted a hypothermizing effect. 4. PRA introduced intracerebroventricularly also induced a decline in core temperature, inhibiting the metabolic rate stimulated by this amine. 5. These results seem to suggest that NA-caused hyperthermia may be controlled through central adrenergic structures, which are effectively blocked by PRA. Besides, we have presented one more proof concerning the antihyperthermizing activity of PRA and its central point of activity catch.

The ontogeny of substance P- and serotonin-like immunoreactivities in the sexually dimorphic cremaster nucleus of the rat spinal cord

This study investigates the ontogeny of two transmitter systems which innervate the sexually dimorphic cremaster nucleus (CN). Since these transmitter systems arise from separate extra- and intraspinal sources, their ontological sequences differ. In males, substance P (SP) innervates CN motoneurons on postnatal day (P) 0, while serotonin (5-HT) is first observed on P2. SP reaches a mature innervation pattern on P20, while 5-HT maturation is prolonged to P40-60. It is suggested that part of the reason for the differing rates of development of 5-HT and SP within CN is due to the source of the innervating fibers; 5-HT descends from the brainstem while SP is of intraspinal origin. On P6, the SP innervation of the dorsal processes of the male CN is so advanced that the spinal cord may be 'sexed' according to the male presence, or the female 'absence', of this SP pattern. In developing and adult females, the 5-HT innervation of the CN is greater than the SP innervation. In addition, the 5-HT and SP innervation of the female CN is greater than the surrounding motor columns. Compared to surrounding ventral gray horn motor nuclei, the CN receives a slightly delayed SP and 5-HT innervation and this may be a reflection of the postnatal formation of the cremaster muscle.

Thermal characterization and transmitter analysis of single units in the preoptic and anterior hypothalamus of conscious ducks

With a multibarrel assembly combining one carbon fiber micropipette as recording electrode and 6 pipettes for microiontophoretic application of drugs, the activity of neurons in the preoptic and anterior hypothalamic (POAH) region was extracellularly recorded in situ in conscious ducks implanted chronically with a device permitting hypothalamic thermal stimulation. Among 355 neurons 17% were identified as warm-responsive (warm units) and 20% as cold-responsive (cold units). In 58 warm and 56 cold units control discharge rates at 40 degrees C local temperature (F40) and temperature coefficients (delta F/delta T) were determined and presented as means +/- SEM. The F40 values of warm units (35.2 +/- 2.3 Imp . s-1) were significantly higher than of cold units (16.3 +/- 1.8 Imp . s-1). The delta F/delta T values (+1.77 +/- 0.15 and -1.77 +/- 0.19 Imp . s-1 . degree C-1) of warm and cold units were not different in absolute terms. In pilot experiments either activation or inhibition by lowering whole-body temperature was observed in both warm and cold units. Microiontophoretic application of one or more of the amines acetylcholine (ACh), 5-hydroxytryptamine (5-HT), and noradrenaline (NA) to warm and cold units revealed differences in their responsiveness to ACh, which more consistently stimulated cold units. NA inhibited the majority of warm units; 5-HT stimulated the majority of cold units. In both warm and cold units NA and ACh differed in their actions, with the latter amine more consistently producing activation.

Changes in cold- and heat-defence following electrolytic lesions of raphe nuclei in the guinea-pig

In conscious guinea-pigs the effects of electrolytic lesions of the nucleus raphe magnus (NRM) and of adjacent areas in the lower brainstem on cold- and heat-defence were studied. Changes in core temperature, heat production and heat loss effectors as well as their threshold temperatures were compared in the same animals before and after lesioning. As an additional index of heat loss, ear skin temperature and a derived parameter--vasomotor index--were also measured. Three days after NRM lesion the fall in core temperature evoked by an exposure to 14-15 degrees C was smaller than before lesion, furthermore the body temperature threshold for shivering increased. Cold-induced heat production was also higher following NRM lesions. Lesions outside the NRM or sham-operation did not influence cold-defence. After NRM lesion heat-defence was also improved; the rise in core temperature elicited by an exposure to 36-37 degrees C was smaller and the body temperature threshold for ear skin vasoconstriction during recovery from hyperthermia decreased. No change in respiratory evaporative heat loss could be observed after NRM lesion. Lesions outside the NRM or sham-operation did not influence heat-defence. An attempt has been made to explain the observed improvements in cold- and heat-defence by discussing relevant data on mechanisms in central temperature control.

Adaptive changes in thermoregulation and their neuropharmacological basis

Adaptive changes of the thermoregulatory system include morphological and functional modifications. The morphological modifications such as changes in body shape and insulation need time periods of months to years to develop, unless they are genetically fixed and appear seasonally. In general, they are preceded by functional modifications, including changes in capacity of the effector systems and changes in regulatory characteristics, which need much less time to develop. These early changes in regulatory characteristics, which can be defined as deviations in threshold and gain of the thermoregulatory responses, have been described and subdivided into short-term (minutes) and long-term (weeks) modifications. Evidence for the participation of monoaminergic brain stem systems in these modifications has been reviewed. On the basis of recent insights into the organization of the thermoregulatory system, and of evaluation of experimental evidence from electrophysiological, neuropharmacological, and neuroanatomical studies it can be concluded that these systems are involved in adaptive modifications. Receiving information from several sensory systems they seem to deliver additional modulatory signals, which may interfere with the processing of specific thermal information at several sites. Theoretically, the central monoamines may participate in the control of thermal input, in the central integration of thermal signals, and in modification of output signals to thermoregulatory effectors. Best documented is their modulatory action on thermosensitive and thermointegrative hypothalamic neurons. There, the monoamines 5-hydroxytryptamine and noradrenaline act as antagonists, which enhance or diminish the effects of thermal afferents mediated by other transmitters. Moreover, the antagonistic monoaminergic systems are interconnected and can influence each other at the level of lower brain stem. The activity in central monoaminergic systems can also be modified by neurohumoral feedback mechanisms from the periphery. By means of these interrelations the vegetative responses of the organism can be corrected and optimized. These interrelations can explain also some cross-adaptive changes in the thermoregulatory threshold for shivering evoked by nonthermal factors such as food intake or long-distance running.

Sympathetic effects of manual and electrical acupuncture of the Tsusanli knee point: comparison with the Hoku hand point sympathetic effects

Sympathetic effects of manual and electrical acupuncture of the Tsusanli knee point were evaluated by thermography in 19 normal subjects under the same procedure used in a previous study using the Hoku hand point. A generalized long-lasting warming (sympathetic inhibition) effect was observed under manual and electrical acupuncture of the Tsusanli point. In addition, a segmentally related short-lasting cooling (sympathetic activation) effect occurred with Tsusanli electrical acupuncture only. The warming effect is consistent with the results of the Hoku study and appears to be a central sympathetic inhibition evoked by acupuncture. The cooling effect was segmentally related to the acupuncture site in both studies. This cooling effect most likely reflects a segmental activation of vasomotor spinal reflexes and not a general emotional arousal. These sympathetic mechanisms may be functionally correlated with central and peripheral mechanisms of acupuncture analgesia.

Effects of capsaicin on central monoaminergic mechanisms in the rat

The acute and chronic effects of capsaicin (s.c.) on the monoamines in the preoptic region + hypothalamus (RPO-H), spinal cord, substantia nigra and striatum were studied. Levels of DOPA, DA, DOPAC, HVA, 3-MT, NA, Trp, 5-HTP, 5-HT and 5-HIAA were determined by means of liquid chromatography (HPLC-EC). In response to acute capsaicin treatment, the levels of DA, DOPAC and DA synthesis rate (DOPA formation) were increased in a dose-dependent manner in the RPO-H and spinal cord. The disappearance rate of NA was accelerated in both regions. In substantia nigra, increased DOPAC levels were found whereas the levels of 3-MT were decreased in striatum after acute capsaicin treatment. Only minor changes on the levels of 5-HT and 5-HIAA in the regions studied were noted. Neonatal or adult capsaicin treatment failed to affect the levels of NA, DA and 5-HT (measured two months or five weeks after injection, respectively) in the regions studied. A capsaicin injection to rats pretreated with the drug as adults did not affect either the monoamines in the RPO-H and spinal cord or the body temperature. In contrast, in rats pretreated with capsaicin as neonates, a second injection of the drug to adult animals elicited hypothermia and changes in monoamines similar to those observed in naive animals.

Different roles of intrahypothalamic and nigrostriatal dopaminergic systems in thermoregulatory responses of the rat

Classically, two neurotransmitters in the brain have been implicated in thermoregulation: 5-hydroxytryptamine and norepinephrine. A dopamine action is less well-known and usually has been studied by means of pharmacological rather than physiological procedures. In the present work using a physiological approach to the problem, the role of different central dopaminergic systems in the thermoregulatory response of rats exposed to cold (4 degrees C) or warm (45 degrees C) environments has been studied. Rostral incertohypothalamic neurons in the medial preoptic area synthesized and released more dopamine in response to a warm but not to a cold environment. On the other hand DA and DOPAC levels in nigrostriatal systems were decreased by cold but not warm environments. The dopaminergic neurons projecting to nucleus accumbens or hypothalamus do not appear to be related to the thermoregulatory response in the rat.

The effect of 6-hydroxydopamine pretreatment on the metabolic response produced by endotoxin in rabbits

The thermoregulatory, effector processes were investigated in rabbits after treatment with 6-hydroxydopamine (6-OHDA) and lipopolysaccharide Escherichia coli (LPS). Pyrogen (1 microgram/kg, i.v.) produced a fever reaction resulting from stimulation of the metabolic rate and heat conservation responses. Pretreatment with 6-OHDA (3 X 500 micrograms, i.c.v.) reduced the metabolic as well as pyretic activity of pyrogen. It is suggested that stimulation of the thermoregulatory heat production which contributes to the febrile rise in body temperature is dependent on the intact adrenergic structures in the central nervous system.

Dopamine and thermoregulation: an evaluation with special reference to dopaminergic pathways

The complex role of dopamine (DA) in the diencephalic mechanisms involved in the control of body temperature is reviewed and evaluated. In the context of the monoamine theory of thermoregulation, catecholaminergic synapses in the anterior hypothalamic pre-optic area, are proposed mediate the pathways in the brain-stem which subserve heat dissipation. Within this theoretical framework, hypothalamic DA is considered to underlie a portion of the functional component of the heat loss system. This deduction is based on pharmacological studies in which both the catecholamine and receptor antagonists have been infused directly into the hypothalamus. In view of the action of DA applied to the substantia nigra and other subcortical structures, the unique anatomical circuitry of the central dopaminergic projections has also been analyzed in terms of specific connections within critical morphological regions related to thermal functions. In particular, the nigro-striatal pathway could be involved in the mediation of one or more of the different aspects of the thermoregulatory system integrating both autonomic and behavioral responses. Finally, an anatomical schema which portrays the suggested mechanisms of DA activity is presented.

Neural relations of cremaster motoneurons, spinal cord systems and the genitofemoral nerve in the rat

The anatomical and biochemical features of primary sensory afferents and the peptidergic innervation of cremaster motoneuron efferents in the genitofemoral (Gf) nerve were analyzed in the rat using immunohistochemical, histochemical, retrograde tracing and lesion methods. Afferent fibers in the Gf nerve were shown to originate from neurons in L1 and L2 dorsal root ganglia (DRG) and to project to L1 to T12.5 in the spinal cord. Some of the DRG neurons giving rise to these fibers contained substance P (SP) or the enzyme fluoride-resistant acid phosphatase but none appeared to contain somatostatin. The dermatome area of the Gf nerve, as determined by plasma extravasation methods, was located in the rostral scrotal and adjacent abdominal region. Identification of cremaster motoneurons by retrograde labelling from the Gf nerve revealed these neurons to be located in the L1 to L2 spinal cord segment, to have prominent rostrocaudally oriented dendritic aborizations and to receive a rich innervation by fibers containing SP, thyrotropin-releasing hormone (TRH) or met-enkephalin (met-Enk). Lesion studies indicated the SP-and met-Enk-containing fibers to be supplied by local intraspinal systems and the TRH-containing fibers by supraspinal systems. In female rats, motoneurons corresponding to the male version of the cremaster motoneuronal pool were less developed and received far fewer peptidergic connections than that observed in males. The multiple neural systems innervating cremaster motoneurons together with sensory afferents in the Gf and other scrotal nerves are suggested to be involved in the contribution of cremaster muscles to thermoregulation of the scrotum.

Capsaicin impairs preoptic serotonin-sensitive structures mediating hypothermia in rats

In an attempt to elucidate the possible mechanisms involved in the development of the thermoregulatory disturbances induced by systemic capsaicin treatment, the effects of 5-HT injected into the preoptic region or into the cisterna magna on the body temperature and on tail skin vasodilation were studied in control and capsaicin-treated rats. Intracisternal 5-HT elicited a comparable decrease in body temperature in both groups of animals. In contrast, intrapreoptic injection of different doses of 5-HT-induced tail skin vasodilation and hypothermia in the controls, but not in the capsaicin-treated rats. It is suggested that changes in the sensitivity of preoptic warm-responsive structures to 5-HT may contribute essentially to the specific thermoregulatory impairment brought about by systemic capsaicin treatment.

Central nervous regulation of body temperature in vertebrates: comparative aspects

Thermal fluctuations affect, and are responded to by, nearly all forms of life. The basic vertebrate template has guided and shaped the ways that animals in this subphylum cope with thermal challenges. This has led to a situation where there are major similarities in the neuronal mechanisms which sense temperature and control the responses to temperature change in all vertebrates, from fish to mammals. The PO/AH is the most important single integration site for temperature regulation and (except for birds) is also important in the sensing of core temperature. Other portions of the brainstem as well as the spinal cord are also involved in thermal control and can sense, integrate, and produce appropriate efferent signals to varying degrees. Peripheral thermal input to the hypothalamic areas is via the brainstem reticular areas. A number of studies has related the thermal response characteristics of CNS single neurons to the thermoregulatory output of intact animals. These studies have been performed on neurons in whole animal, brain slice, and tissue culture preparation. These neurophysiological studies of central neurons are informative, but are sometimes difficult to interpret because of the chronic lack of definite criteria to differentiate generalized thermal sensitivity from thermal sensitivity utilized for regulating body temperature. Recent neuroanatomical work has illustrated that many areas previously implicated in the thermoregulatory network (such as the septum, various hypothalamic nuclei, the midbrain reticular formation, and the midbrain raphé nuclei) receive direct projections from PO/AH neurons. When compared, the neurophysiological and neuroanatomical characteristics of the preoptic nucleus and anterior hypothalamic area are similar, but not identical. The broad differences in the responses that vertebrates utilize to deal with thermal change is largely determined by the respiratory medium (water or air) and whether metabolic energy (endothermy) or ambient temperature (ectothermy) is of primary importance in the determination of internal temperature. A number of physiological systems are perturbed in water breathing ectotherms when the ambient temperature is altered. In these vertebrates long-term acclimation is very important and has a major effect on temperature selection. Air breathing ectotherms are less adversely affected by temperature change; long-term thermal acclimation is less important and has little effect upon temperature selection; large thermal changes are often initiated by these animals. Endotherms rely on insulation and a high, variable metabolic rate to maintain a constant internal temperature.(ABSTRACT TRUNCATED AT 400 WORDS)

Changes in the thermal characteristics of hypothalamic neurons during sleep and wakefulness

The characteristics of the mammalian thermoregulatory system are dependent upon arousal state. During NREM sleep thermoregulatory mechanisms are intact but body temperature is regulated at a lower level than during wakefulness. In REM sleep thermoregulatory effector mechanisms are inhibited and thermal homeostasis is severely disrupted. Thermosensitivity of neurons in the preoptic/anterior hypothalamus (POAH) was determined for behaving kangaroo rats (Dipodomys deserti) during electrophysiologically defined wakefulness, NREM sleep and REM sleep to elucidate possible neural mechanisms for previous findings of state-dependent changes in thermoregulation. Thirty cells were tested during at least two arousal states. During wakefulness, 70% of the recorded cells were sensitive to changes in local temperature, with the number of warm-sensitive (W) cells outnumbering cold-sensitive (C) cells by 1.6:1. In NREM sleep, 43% of the cells were thermally sensitive, with the ratio of W:C remaining the same as in wakefulness. In REM sleep only two cells were thermosensitive (both W). The decrease in neuronal thermosensitivity of POAH cells during REM sleep parallels findings of inhibition of thermoregulatory effector responses during REM, although further work is necessary to determine the source and nature of the inhibition.

Nonshivering thermogenesis

Nonshivering thermogenesis was originally defined as a cold-induced increase in heat production not associated with the muscle activity of shivering. Recent research shows it to be a metabolic process located primarily in brown adipose tissue and controlled by the activity of the sympathetic nervous supply of this tissue. Another stimulus to sympathetic nervous activity, the ingestion of food, promotes diet-induced thermogenesis in brown adipose tissue. Brown adipose tissue grows and regresses in accordance with the extent to which it is stimulated, either by cold or by diet, and the capacity of the animal for cold-induced nonshivering thermogenesis and diet-induced thermogenesis increases or decreases accordingly. In certain hibernators another stimulus, photoperiod, promotes growth or regression of brown adipose tissue. The neural regulation of thermogenesis in brown adipose tissue is thus not only part of the central control mechanisms involved in thermoregulation but also part of those involved in the regulation of energy balance. In hibernators , such as the hamster, the neural regulation of thermogenesis in brown adipose tissue includes, in addition, central components that control the function of brown adipose tissue during entry into and arousal from hibernation and pineal or melatonin-related components that control its growth in response to photoperiod. In animals which become intermittently torpid, such as the mouse, the regulation includes in addition central components that control the function of brown adipose tissue during entry into and arousal from torpor. The central neural components involved in control of thermoregulation are better understood than are those involved in the regulation of energy balance. Studies of animal with hypothalamic obesity indicate that the control of diet-induced thermogenesis in brown adipose tissue requires the participation of the ventromedial region of the hypothalamus whereas the control of cold-induced nonshivering thermogenesis does not. The importance of comparative studies in different species is emphasized since any neural model for the control of brown adipose tissue thermogenesis is likely to apply in detail only to the species for which it was developed.

Central short-term cold adaptation in the guinea-pig

The responses of seventeen single units to changes in skin temperature were recorded in fifteen guinea-pigs anaesthetized with urethane. All units were located in the subcoeruleus region which has been discussed as part of the thermoafferent system. Thermal stimuli were applied to different skin areas. The receptive fields of sixteen cold-responsive units were found to be parts of the abdominal and thoracic skin. The cold-responsive units could be subdivided into two groups. Ten units showed the known classic cold-responsive steady state response. A short-term thermal adaptation was seen in six units. These units had peak activities at skin temperatures between 22 degrees C and 29 degrees C and decreased their firing rates within 5 to 40 minutes when the temperature of the receptive skin area was kept constant in the range between 20 degrees C and 29 degrees C. This short-term cold-adaptive effect could be reversibly abolished by warming the corresponding skin area for a certain period of time. The short-term adapting neurones could be conceived of as the neurophysiological correlate to cold-adaptive changes in thermogenic responses seen in three guinea-pigs. Oxygen uptake and shivering activity were reduced in animals, which had reached approximately constant skin and core body temperature during sustained external cooling.