Punctate Administration of Ficin as a human and animal model of non-histaminergic itch.

BACKGROUND: Ficin, a cysteine protease derived from fig-tree latex, has been reported to elicit itch and nociceptive sensations, though quantitative sensory studies are lacking. Cowhage containing the pruritic cysteine Mucunain, on the contrary, has been widely studied as activating polymodal nociceptors and eliciting a histamine-independent itch. OBJECTIVES: We tested whether ficin in heat-inactivated cowhage spicules would elicit itch and nociceptive sensations in humans, and analogous behaviours in mice, which are similar to those evoked by native cowhage, and whether these behaviours in mice were dose-dependent when ficin was injected intradermally. METHODS: Human volunteers rated the magnitude of itch and nociceptive sensations evoked by either native cowhage spicules or heat-inactivated spicules soaked in 1, 10 or 100 mg/mL ficin (0.03, 0.3 and 3 ng of ficin in spicule tip), applied to forearm. In mice, itch-like scratching and nociceptive-like wiping were recorded in response to either native cowhage, to heat-inactivated spicules that were either inactive or contained 100 mg/mL ficin, or to intradermal injections of 1.25, 2.5 or 5 µg/ 5 µL, each treatment applied to the cheek. RESULTS: The dose of 100 mg/mL ficin in spicules evoked comparable magnitudes of itch, nociceptive sensations and areas of cutaneous dysesthesia as native cowhage in humans and comparable itch-like scratching and pain-like wiping behaviours in mice. But to elicit similar behaviours when injected intradermally in mice a greater amount of ficin (1.25 µg) was required. CONCLUSION: Spicule delivery or intradermal injection of ficin elicits behaviours in mice that model itch and nociceptive sensations in humans, suggesting that ficin may be useful in translating mechanistic research on the neural mechanisms of pruritic and nociceptive effects of cysteine proteases between the two species.

Pruritic and nociceptive sensations and dysesthesias from a spicule of cowhage.

Although the trichomes (spicules) of a pod of cowhage (Mucuna pruriens) are known to evoke a histamine-independent itch that is mediated by a cysteine protease, little is known of the itch and accompanying nociceptive sensations evoked by a single spicule and the enhanced itch and pain that can occur in the surrounding skin. The tip of a single spicule applied to the forearm of 45 subjects typically evoked 1) itch accompanied by nociceptive sensations (NS) of pricking/stinging and, to a lesser extent, burning, and 2) one or more areas of cutaneous dysesthesia characterized by hyperknesis (enhanced itch to pricking) with or without alloknesis (itch to stroking) and/or hyperalgesia (enhanced pricking pain). Itch could occur in the absence of NS or one or more dysesthesias but very rarely the reverse. The peak magnitude of sensation was positively correlated for itch and NS and increased (exhibited spatial summation) as the number of spicules was increased within a spatial extent of 6 cm but not 1 cm. The areas of dysesthesia did not exhibit spatial summation. We conclude that itch evoked by a punctate chemical stimulus can co-exist with NS and cutaneous dysesthesias as may occur in clinical pruritus. However, cowhage itch was not always accompanied by NS or dysesthesia nor was a momentary change in itch necessarily accompanied by a similar change in NS or vice versa. Thus there may be separate neural coding mechanisms for itch, nociceptive sensations, and each type of dysesthesia.

Exhalation of gaseous nitric oxide by rats in response to endotoxin and its absorption by the lungs.

Rats injected with a lipopolysaccharide endotoxin produce detectable concentrations of nitric oxide gas (NO) in the expired air within 60 min. The concentration of NO reaches a plateau at 3 h. Production of the NO is dose dependent on lipopolysaccharide, and at a dose of 1 mg/kg i.v., lipopolysaccharide alveolar concentrations of > 260 parts per billion are observed. NO synthase inhibitors suppress this NO production in response to endotoxin. Experiments were conducted to ascertain the site of origin of this NO and to measure the capacity of the lungs to absorb NO from alveolar air. Results indicate that the endotoxin-induced NO originates from within the lungs themselves and that the lungs have the capacity to absorb > 60% of NO that is presented to them. Lung tissues absorb approximately 44-47% of the NO load, blood carries away between 15 and 19%, while the remainder is exhaled in the expired air. It is proposed that the exhalation of NO might prove useful as an early biomarker for acute lung injury.

A study of the mechanism of action of the mild analgesic dipyrone.

The mechanism of action for the mild analgesics is controversial. While some have proposed that they inhibit prostaglandin synthesis in the central nervous system to interfere with nociceptive mediators in the brain, others have proposed that they act directly on nociceptive neural pathways to produce analgesia. This class of drugs also possesses antipyretic activity. We examined the antipyretic effect of one such drug, dipyrone, because this might elucidate the mechanism of its analgesic activity. In rats implanted with a femoral vein catheter and a cannula guide tube aimed towards the organum vasculosum laminae terminalis (OVLT) in the brain, an i.v. injection of 2 micrograms/kg interleukin-1 beta (IL-1 beta) produced a fever of 0.38 +/- 0.07 degrees C while an injection of 20 ng prostaglandin E1 (PGE) into the OVLT produced a fever of 1.18 +/- 0.18 degrees C. Dipyrone (25 mg/kg, i.v.) decreased the IL-1 beta fever but had no effect on the PGE fever. After pretreatment with the immunoadjuvant, zymosan, the IL-1 beta fevers were enhanced to equal those induced by PGE. Only 0.1 micrograms/kg, i.v. IL-1 beta raised body temperature by 1.20 +/- 0.10 degrees C. An increased dose of dipyrone (50 mg/kg, i.v.) was required to attenuate this IL-1 beta fever; however, the PGE fever remained unaffected by this treatment with dipyrone. Thus, dipyrone treatment blocks IL-1 beta fever where synthesis of prostaglandin is a crucial step in the febrile process, but it has no effect on PGE fever where synthesis is bypassed. This suggests that dipyrone, probably through its active metabolites, inhibits prostaglandin synthesis to induce antipyresis and, by analogy, analgesia as well.

ACTH response induced in capsaicin-desensitized rats by intravenous injection of interleukin-1 or prostaglandin E.

1. We investigated whether afferent nerves are involved in the development of adrenocorticotrophic hormone (ACTH) responses induced either by systemic administration of interleukin-1 beta (IL-1 beta) and prostaglandin E2, or by psychological stress. The capsaicin desensitization method was used to impair afferent C fibres and we compared the ACTH responses between capsaicin desensitized and vehicle pretreated control rats. 2. The present results showed that the capsaicin desensitized rats had significantly smaller increases in plasma ACTH than the control rats in response to intravenous injection of IL-1 beta or prostaglandin E2. 3. There were no significant differences between the capsaicin desensitized and control rats in the ACTH responses induced by cage switch stress. 4. The capsaicin desensitized rats responded to intravenous injection of corticotrophin releasing factor (CRF) with a greater increase in the plasma level of ACTH than the control rats, indicating that capsaicin pretreatment resulted in augmentation of pituitary gland sensitivity to CRF. 5. These results suggest that afferent neurons play an important role in the ACTH responses induced by systemic injection of IL-1 beta or prostaglandin E2.

Calcium channel blockers inhibit endogenous pyrogen fever in rats and rabbits.

We have previously shown that febrile responses in both rats and rabbits are elicited by the intravenous injection of a semipurified endogenous pyrogen (EP) prepared from human monocytes. We are now presenting evidence that these febrile responses are mediated via activation of Ca2+ channels by EP. The febrile responses of male New Zealand White rabbits and Sprague-Dawley rats to a standard dose of EP were determined at their respective thermoneutral ambient temperatures. The animals were then treated with Ca2+ channel blocker verapamil (7.5 mg/kg iv) 30-60 min before the EP challenge. In every case the febrile response to EP was markedly attenuated after verapamil pretreatment, while administration of verapamil by itself had no detectable effect on body temperature. Another Ca2+ channel blocker, nifedipine (5 mg/kg iv), was shown to possess antipyretic activity in rats also. To localize where in the fever pathway these Ca2+ channel blockers were acting, we investigated the effect of verapamil at the same dose on fevers that were produced by microinjection of prostaglandin E (PGE) directly into the brain. These PGE fevers were unaffected by verapamil pretreatment, indicating that the antipyretic action of Ca2+ channel blockers occurs before the formation of PGE in response to EP stimulation. The most likely locus of action is the activation of the enzyme phospholipase A2, which regulates the production of arachidonic acid from cellular phospholipids in the prostanoid cascade.

Site of action of calcium channel blockers in inhibiting endogenous pyrogen fever in rats.

We have demonstrated that the Ca2+ channel blocker verapamil, administered intravenously, exerts an antipyretic effect on the febrile responses of rats to intravenously injected endogenous pyrogen (EP). We have also shown that the same intravenous dose of verapamil is ineffective in blocking fevers induced by the microinjection of exogenous prostaglandin E (PGE) into the organum vasculosum laminae terminalis (OVLT) of rats. Experiments were conducted to determine whether the site of this verapamil antipyresis was in the OVLT itself. The febrile responses of six male Sprague-Dawley rats to EP were determined at thermoneutrality. Verapamil (10 micrograms/rat) was microinjected directly into the OVLT, and the febrile responses to the EP dose were redetermined 15-30 min later. In every case the EP fevers were attenuated after verapamil pretreatment. Intra-OVLT injections of verapamil alone were without effect on body temperature. When the same dose of verapamil was injected into the OVLT 15 min before the injection of PGE into the same site, it had no effect on the ensuing PGE-induced fever. In view of the fact that less than 1/250th of the effective systemic dose of verapamil, when injected into the OVLT, was equally effective in blocking the EP fevers, we conclude that verapamil acts within the OVLT to block fever rather than peripherally. Furthermore, because verapamil administered into the OVLT does not block PGE fevers, it is unlikely that PGE produces fever by acting as a Ca2+ ionophore on hypothalamic neurons.

Effects of cold and capsaicin desensitization on prostaglandin E hypothermia in rats.

Intraperitoneal injection of prostaglandin E1 (PGE) produces a transient hypothermia in rats that lasts 1-2 h. Rats exposed to an ambient temperature (Ta) of 26 degrees C displayed a decrease in rectal temperature (Tre) of 0.95 +/- 0.12 degrees C (SE) after injection with PGE (100 micrograms/kg ip). Hypothermia was produced mainly by heat losses, as indicated by increases in tail blood flow. At Ta of 4 degrees C, PGE produced a comparable fall in Tre of 1.00 +/- 0.14 degrees C. However, in the cold the hypothermia was caused solely by decreases in heat production. These results indicate that the PGE-induced hypothermia is not the result of a peripheral vasodilation induced by the direct action of PGE on the tail vascular smooth muscle but is a central nervous system-mediated response of the thermoregulatory system induced by PGE within the peritoneal cavity. Capsaicin injected subcutaneously induces a transient hypothermia in rats because of stimulation of the warm receptors. If administered peripherally in sufficient amounts, it is reputed to impair peripheral warm receptors so that they become desensitized to the hypothermic effects of capsaicin. We measured PGE-induced hypothermias in rats both before and after capsaicin desensitization at Ta of 26 degrees C. Before desensitization the hypothermia was -1.14 +/- 0.12 degrees C, whereas after capsaicin treatment the PGE-induced hypothermia was -0.34 +/- 0.17 degrees C. The biological effects of capsaicin are diverse; however, based on current thinking about the thermoregulatory effects of capsaicin desensitization, our results indicate that peripheral warm receptor pathways are in some manner implicated in the hypothermia induced by intraperitoneal PGE.

Immunoadjuvants enhance the febrile responses of rats to endogenous pyrogen.

The febrile responses of male Sprague-Dawley rats to a semipurified endogenous pyrogen produced from human monocytes were characterized by establishing fever dose-response curves. The animals were then injected intravenously with a number of substances that possessed the common properties of stimulating the phagocytic activity of the cells of the reticuloendothelial system and of acting as immunoadjuvants. The substances used were zymosan, lipopolysaccharide endotoxin, and muramyl dipeptide. Three days after any of these immunoadjuvants were injected, the fever sensitivity of the rats was remeasured. In each case, the slope of the fever dose-response curve tripled, and in some instances the response threshold for fever response was reduced by factors of three to eight. Furthermore, the maximum increase in body temperature produced by the endogenous pyrogen was more than doubled after immunoadjuvant treatment. By contrast latex beads, which are also phagocytized by the cells of the reticuloendothelial system but do not subsequently increase their phagocytic index nor do they enhance immune responses, had no effect on the fever sensitivity of rats in response to endogenous pyrogen. In the light of these findings, it is suggested that the febrile responses of rats to endogenous pyrogen are mediated in some manner by cells that possess some of the properties of reticuloendothelial cells. The location of these putative cells must be close to the circulation, because the immunoadjuvants used in this study were, for the most part, large molecular weight molecules that could not cross the blood-brain barrier easily.

Enhancement of the febrile responses of rats to endogenous pyrogen occurs within the OVLT region.

The febrile responses of male Sprague-Dawley rats to a semi-purified endogenous pyrogen (EP) derived from human monocytes are markedly enhanced 3 days after the animals are intravenously injected with a variety of immunoadjuvants. The present study was designed to investigate the site within the body at which these substances act to produce this febrile-enhancing phenomenon. Stainless steel microinjection cannula guide tubes were implanted within the region of the organum vasculosum lamina terminalis (OVLT) of the rats and control febrile dose-response curves to EP were established. Minute quantities of the immunoadjuvants zymosan, lipopolysaccharide endotoxin, and the synthetic adjuvant peptide, muramyl dipeptide, were microinjected into the OVLT region and 3 days later, the febrile responses of the animals were retested. In each case the febrile response elicited by a standard dose of EP was more than doubled, the slope of the fever dose-response curve was tripled, and the dose threshold was lowered by a factor of four to five. These responses are identical with those produced when much larger amounts of these immunoadjuvants are injected intravenously, and, thus, we conclude that the site of action of these substances in enhancing fever in response to EP resides in or near the OVLT region. It is proposed that EP stimulates a type of reticuloendothelial cell residing within the OVLT to release prostaglandin E, which in turn crosses the blood-brain barrier to effect the changes in the thermoregulatory neurons of the preoptic anterior hypothalamic area that result in fever.

A comparison of the febrile responses of the Brattleboro and Sprague-Dawley strains of rats to endotoxin and endogenous pyrogens.

The febrile responses of homozygous (di/di) Brattleboro rats, to both intravenous endogenous pyrogen and to a lipopolysaccharide endotoxin, were compared with those of normal Sprague-Dawley rats. There were no detectable differences between the fever curves of the two strains in response to endogenous pyrogen. Brattleboro rats, which are deficient in the neuropeptide arginine vasopressin (AVP), displayed fevers that were both qualitatively and quantitatively indistinguishable from those of normal Sprague-Dawley rats that do not suffer from congenital diabetes insipidus. It is concluded that the absence of AVP-containing cells in Brattleboro rats is not an important factor in determining the nature of their febrile responses to endogenous pyrogen. More remarkable, however, were the divergent febrile responses of the two strains to intravenously injected endotoxin. Normal rats displayed hypothermic responses, whereas the Brattleboro rats became febrile. By 2 h after the injection of endotoxin, body temperatures in both strains had returned to normal. Three hours after the rats had been exposed to endotoxin, both strains were found to be totally refractory to endogenous pyrogen. However, when both strains of rats were tested to endogenous pyrogen 3 days later, their febrile responses were more than double the magnitude of their initial control responses. These alterations in the febrile responsiveness of rats occurring at different times after the injection of endotoxin appear to be related to the effects that endotoxin has on the cells of the reticuloendothelial system, over the same time course.

Comparison of febrile responsiveness of rats and rabbits to endogenous pyrogen.

The fever responses of rats and rabbits were compared in detail using a single common source of semipurified endogenous pyrogen prepared from human monocytes. The characteristics and dynamics of the fever-response curves for each species were examined and their dose-response curves were determined and compared. The fevers displayed by rats were qualitatively similar to those of rabbits, but, typically, they developed and terminated more rapidly than those of rabbits. Rabbits were much more sensitive to the endogenous pyrogen than rats. The threshold dose of pyrogen required to elicit a fever was 5 times lower in the rabbit, and the slope of the rabbit's dose-response curve was 1.5 times steeper than that of the rat. The maximum fevers attainable in rabbits were approximately twice those attainable in rats. It was also shown that the more rapid febrile responses of the rat were not due to the 10-fold smaller mass of the rat; instead, we proposed that this difference was more likely due to a closer diffusional proximity of the pyrogen receptor sites to the circulation in rats. The lower sensitivity of the rat to endogenous pyrogen was attributed to a relative insensitivity of the pyrogen receptor sites in rats in the translation of the endogenous pyrogen stimulus into fever.

Hypothalamic thermosensitivity in capsaicin-desensitized rats.

In rats, we tested the hypothesis that capsaicin desensitization reduces hypothalamic warm thermosensitivity. We locally heated and cooled the hypothalamus using water-perfused thermodes while observing thermoregulatory variables. In untreated rats, a small dose of capsaicin had profound effects on thermoregulation. However, desensitizing rats to capsaicin had no effect on hypothalamic thermosensitivity for metabolic rate or changes in body temperature due to displacements of hypothalamic temperature. Contrary to current opinion, we conclude that capsaicin desensitization does not alter hypothalamic thermosensitivity to warm or cold.

The effect of low ambient temperature on the febrile responses of rats to semi-purified human endogenous pyrogen.

The febrile responses of Sprague-Dawley rats to semi-purified human endogenous pyrogen were studied at a thermoneutral ambient temperature (26 degrees C) and in the cold (3 degrees C). It was found that while rats developed typical monophasic febrile responses at thermoneutrality, febrile responses were absent in the cold-exposed rats. Experiments were conducted to determine whether this lack of febrile responses in cold-exposed rats was due to an inability of these animals to generate or retain heat in the cold. Thermogenesis and vasoconstriction were stimulated in cold-exposed rats by selectively cooling the hypothalamus, using chronically implanted thermodes. It was shown that, using this stimulus, metabolic rate could be increased by more than 50 percent and body temperature could be driven up at a rate of 5 degrees C/hour in rats exposed to the cold. Therefore, it was concluded that the lack of febrile responses of cold-exposed rats to pyrogen is in no way due to a physical or physiological inability to retain heat. Instead, it appears that in some manner cold exposure suppresses the sensitivity or responsiveness of the rat to pyrogenic stimuli.

An analysis of the purinergic component of active muscle vasodilatation obtained by electrical stimulation of the hypothalamus in rabbits.

In anaesthetized rabbits, electrical stimulation of the hypothalamus in areas analogous to the defence area in cats produces the 'defence reaction.' This response includes signs of arousal and a large increase in blood flow to skeletal muscle in the hind limb caused by a vasodilatation in the skeletal muscle vasculature. The vasodilatation is a sympathetic response, and it is not dependent upon muscle activity in the hind limb. The muscle vasodilatation is insensitive to alpha-adrenoceptor, beta-adrenoceptor, cholinoceptor and histamine receptor antagonists. Intra-arterial injections of the purinoceptor agonists, adenosine triphosphate (ATP) and adenosine, mimic the vasodilatation produced by electrical stimulation. The P1-purinoceptor blocker, aminophylline, attenuates adenosine-induced vasodilatation, but it does not affect the vasodilatation produced by ATP or hypothalamic stimulation. The P2-purinoceptor blocker, antazoline, attenuates the vasodilatation produced by both ATP and hypothalamic stimulation. Our results suggest that the muscle vasodilatation produced by hypothalamic stimulation is mediated by purinergic nerves which release ATP and act on P2-purinoceptors.

Inhibition of shivering during restraint hypothermia.

Restraint hypothermia has often been described, but its cause has never been clarified. We hypothesized that it might be due to a suppression of shivering thermogenesis. Thus, we restrained conscious rats in an ambient temperature of 2 degrees C while measuring rectal (Tre) and tail skin temperatures, metabolic rate (MR), and shivering activity. When rats were cold exposed but not restrained, Tre fell 1.4 +/- 0.2 degrees C (SE) during the 1st h. When these same rats were restrained, Tre fell at a rate of 6.5 +/- 0.2 degrees C/h. MR averaged 15.7 +/- 1.4 W/kg for the unrestrained rats, but it averaged only 9.0 +/- 1.1 W/kg for the restrained rats. The restrained rats showed no signs of shivering. The animals were then subjected to a restraint adaptation regimen and then reexposed to cold. Restraint now produced a fall in Tre of only 2.6 +/- 0.7 degrees C/h. The animals shivered and generated an MR of 15.8 +/- 0.9 W/kg. Naive rats became hypothermic because restraint suppressed shivering activity. However, adapted rats continued to shiver and remained normothermic. We suggest that a stressful or threatening situation, such as restraint for a naive rat, inhibits shivering and leads to hypothermia in a cold environment. This would not occur in adapted rats because restraint is no longer stressful.