Inhibitory neurogenic modulation of histamine-induced cutaneous plasma extravasation in the pigeon

The neurohumoral modulation of the permeability increasing effect of histamine was studied in pigeon skin. Substances were administered through plasmapheresis capillaries inserted into the dorsal wing skin and the protein contents of the perfusates were determined by a quantitative method. The vascular labelling technique was also utilized to histologically identify leaky blood vessels. In the innervated skin histamine evoked a significant, dose-dependent plasma extravasation which was markedly augmented by the coadministration of a specific galanin receptor antagonist, galanin-1-16-bradykinin-2-9-amide (M35). Chronic cutaneous denervation per se resulted in a significant elevation of the permeability-enhancing effect of histamine. In the denervated skin this response was not affected by M35 but was significantly inhibited by galanin. It is concluded that in the normally innervated skin endogenous galanin may exert a neurogenic tonic inhibitory effect on histamine-induced plasma leakage. It is suggested that sensory nerves possess not only pro-inflammatory, but also anti-inflammatory (inhibitory) sensory-efferent functions.     

Several mediators appear to interact in neurogenic inflammation

Plasma protein extravasation was studied in the rat abdominal skin. Substance P (SP), neurokinin A (NKA) and B (NKB) were found to induce extravasation with a threshold dose of about 1 pmol. Calcitonin gene-related peptide (CGRP) caused no or little extravasation alone but it potentiated the action of SP, NKA, NKB, and physalaemin. The potentiation of the SP-induced extravasation was unaffected by pretreatment with capsaicin, indomethacin or compound 48/80, it was reduced by neuropeptide Y or pretreatment with mepyramine plus cimetidine, and was abolished in streptozotocin diabetic rats. CGRP augmented extravasation induced by histamine, reduced the effect of ATP or adenosine and did not alter extravasation by serotonin, bradykinin or neurotensin. These results indicate that in addition to SP the novel mammalian tachykinins NKA and NKB may be considered as mediator candidates for neurogenic plasma extravasation. CGRP is a possible mediator of antidromic vasodilation. Furthermore, CGRP potentiates the extravasation caused by coexisting tachykinins and could thereby augment neurogenic inflammation. The diverse interactions of CGRP with other inflammatory mediators suggest multiple sites of action.     

Conditioning pain stimulation does not affect itch induced by intra-epidermal histamine pricks but aggravates neurogenic inflammation in healthy volunteers

This study investigated whether itch induced by intra-epidermal histamine is subjected to modulation by a standardized conditioned pain modulation (CPM) paradigm in 24 healthy volunteers. CPM was induced by computer-controlled cuff pressure algometry and histamine was introduced to the volar forearm by skin prick test punctures. Moreover, neurogenic inflammation and wheal reactions induced by histamine and autonomic nervous system responses (heart rate variability and skin conductance) were monitored. CPM did not modulate the intensity of histamine-induced itch suggesting that pruriceptive signaling is not inhibited by pain-recruited endogenous modulation, however, CPM was found to aggravate histamine-induced neurogenic inflammation, likely facilitated by efferent sympathetic fibers.     

Relationships between permeable vessels, nerves, and mast cells in rat cutaneous neurogenic inflammation

Electrical stimulation of rat sensory nerves produces cutaneous vasodilation and plasma protein extravasation, a phenomenon termed "neurogenic inflammation". Rat skin on the dorsum of the paw developed neurogenic inflammation after electrical stimulation of the saphenous nerve. In tissue sections, the extravasation of the supravital dye monastral blue B identified permeable vessels. Mast cells were identified by toluidine blue stain. Permeable vessels were significantly more dense in the superficial 120 microns of the dermis than in the deeper dermis, whereas mast cells were significantly more frequent in the deeper dermis. The relationships between nociceptive sensory nerve fibers, permeable vessels, and mast cells were examined by indirect immunohistochemistry for calcitonin gene-related peptide (CGRP), neurokinin A (NKA), and substance P (SP). CGRP-, NKA-, and SP-containing nerves densely innervated the superficial dermis and appeared to innervate the vessels that became permeable during neurogenic inflammation. In contrast, mast cells were not associated with either permeable vessels or nerve fibers. These data suggest that electrical stimulation of rat sensory nerves produces vascular permeability by inducing the release of neuropeptides that may directly stimulate the superficial vascular bed. Mast cells may not be involved in this stage of cutaneous neurogenic inflammation in rat skin.     

Neurogenic inflammation in the chicken (Gallus gallus var domesticus)

1. Neurogenic inflammation has been studied in the anaesthetized adult hen using a variety of different stimuli.2. Plasma extravasation was produced following antidromic stimulation of the external mandibular ramus of the trigeminal nerve which innervates the skin at the angle of the jaw and the anterior part of the wattle.3. Stimulation of the wattle by external application of mustard oil, thermal and mechanical stimuli, as well as intradermal injection of substance P and bradykinin, all produced plasma extravasation.4. These results demonstrate that, in contrast to previous findings in the pigeon, at least in the trigeminal of the chicken peripheral C-fibre nociceptors have similar physiological characteristics in relation to the neurogenic inflammatory mechanism to those seen in mammals.     

Inhibitory effect of PACAP-38 on acute neurogenic and non-neurogenic inflammatory processes in the rat

Inhibitory actions of pituitary adenylate cyclase activating polypeptide (PACAP) have been described on cellular/vascular inflammatory components, but there are few data concerning its role in neurogenic inflammation. In this study we measured PACAP-like immunoreactivity with radioimmunoassay in the rat plasma and showed a two-fold elevation in response to systemic stimulation of capsaicin-sensitive sensory nerves by resiniferatoxin, but not after local excitation of cutaneous afferents. Neurogenic plasma extravasation in the plantar skin induced by intraplantar capsaicin or resiniferatoxin, as well as carrageenan-induced paw edema were significantly diminished by intraperitoneal PACAP-38. In summary, these results demonstrate that PACAP is released from activated capsaicin-sensitive afferents into the systemic circulation. It diminishes acute pure neurogenic and mixed-type inflammatory reactions via inhibiting pro-inflammatory mediator release and/or by acting at post-junctional targets on the vascular endothelium.     

A Galanin Receptor Subtype 1 Specific Agonist

The chimeric peptide M617, galanin(1–13)-Gln¹⁴-bradykinin(2–9)amide, is a novel galanin receptor ligand with increased subtype specificity for GalR1 and agonistic activity in cultured cells as well as in vivo. Displacement studies on cell membranes expressing hGalR1 or hGalR2 show the presence of a high affinity binding site for M617 on GalR1 (K_i=0.23±.12 nM) while lower affinity was seen towards GalR2 (K_i=5.71±1.28 nM) resulting in 25-fold specificity for GalR1. Activation of GalR1 upon stimulation with M617 is further confirmed by internalization of a GalR1-EGFP conjugate. Intracellular signaling studies show the ability of M617 to inhibit forskolin stimulated cAMP formation with 57% and to produce a 5-fold increase in inositol phosphate (IP) accumulation. Agonistic effects on signal transduction are shown on both receptors studied after treatment with M617 in the presence of galanin. In noradrenergic locus coeruleus neurons, M617 induces an outward current even in the presence of TTX plus Ca²⁺, high Mg²⁺, suggesting a postsynaptic effect. Intracerebroventricular (i.c.v.) administration of M617 dose-dependently stimulates food uptake in rats while, in contrast, M35 completely fails to affect the feeding behavior. Spinal cord flexor reflex is facilitated by intrathecal (i.t.) administration of M617 as well as galanin with no significant change upon pre-treatment with M617. M617 dose dependently antagonizes the spinal cord hyperexcitablility induced by C-fiber conditioning stimulus and does neither enhance nor antagonize the effect of galanin. These data demonstrate a novel galanin receptor ligand with subtype specificity for GalR1 and agonistic activity, both in vitro and in vivo.     

An extract of rat submandibular glands activates platelets and enhances cutaneous vascular permeability in rats and guinea pigs

Washed, [3H]serotonin-labeled platelets from rats and guinea pigs were stimulated in vitro with a novel protein extracted from rat submandibular salivary glands (RS-PAP) and with the phospholipid platelet- activating factor 1-0-alkyl-2-acetyl-sn-glycero-3-phosphorylcholine (AGEPC). Rat platelets, which are refractory to AGEPC stimulation, underwent shape-change, aggregation and secretion of [3H]serotonin in response to graded doses of RS-PAP and AGEPC. Intradermal injections of histamine, RS-PAP and AGEPC caused a dose-related increase in local microvascular permeability in rats, as measured by the extravasation of plasma containing Evans blue dye. Similarly, histamine, RS-PAP and AGEPC increased cutaneous vascular permeability when injected intradermally in guinea pigs. The vascular permeability induced by histamine and RS-PAP, but not by AGEPC, was partially inhibited by pretreatment with an antihistamine (diphenhydramine HCl). Pretreatment of guinea pigs with captopril, an inhibitor of angiotensin-converting enzyme (ACE), partially inhibited cutaneous responses to subsequent intradermal injections of histamine, RS-PAP and AGEPC. Regardless of pretreatment with diphenhydramine or captopril, skin test sites injected with large amounts of RS-PAP became hemorrhagic within minutes and necrotic within 12 hours.     

Neurogenic inflammation, vascular permeability, and mast cells. II. Additional evidence indicating that mast cells are not involved in neurogenic inflammation.

Activation of cutaneous sensory nerves induces vasodilatation and vascular permeability, i.e., neurogenic inflammation. We examined the histology and possible mast cell involvement in cutaneous neurogenic inflammation induced by electrical nerve stimulation (ENS). Three lines of evidence indicated that mast cells were not involved in rodent cutaneous neurogenic inflammation induced by electrical stimulation of the saphenous nerve. 1) Most mast cells (86.5% of all mast cells in the dorsal skin of the paw) were found in the deep dermis, whereas vessels developing increased vascular permeability after nerve stimulation (visualized with the supravital dye Monastral blue B, a macro-molecular tracer) were localized predominantly in the superficial dermis. By contrast, i.v. substance P, which also causes increased cutaneous vascular permeability, predominantly caused deeper vessels to leak. As analyzed by electron microscopy, the vessels that developed permeability in response to nerve stimulation, and were thereby stained with Monastral blue B, were found to be exclusively postcapillary venules. 2) Disodium cromoglycate (DSCG), a mast cell stabilizing compound, inhibited the cutaneous vascular permeability induced by intradermal injections of anti-IgE in a dose-dependent manner. By contrast, vascular permeability induced by ENS was not influenced by disodium cromoglycate treatment. 3) ENS and i.v. substance P both induced cutaneous vascular permeability in mast cell-deficient W/Wv mice, despite the fact that their skin contained only 4.7% of the mast cells present in their normal +/+ litter mates. The magnitude of ENS-induced vascular permeability responses in W/Wv mice were similar to control +/+ and BALB/c mice. This study supports our earlier observations suggesting that mast cell activation is not essential for the initial, vascular permeability phase of neurogenic inflammation in rodent skin.     

Triggering of the vascular permeability reaction by activation of the Hageman factor-prekallikrein system by house dust mite proteinase

A 30-kilodalton (kDa) proteinase from the house dust mite Dermatophagoides farinae (Df-proteinase) was recently purified (Takahashi et al. (1990) Int. Arch. Allergy Appl. Immunol. 91, 80-85). In this paper we detailed the biological activities of the Df-proteinase. The activation of the kinin cascade by Df-proteinase was examined in vitro by using purified guinea pig Hageman factor (HF), prekallikrein (PK) and high-molecular-weight kininogen (HMWK) and the effect of this proteinase on endogenous human plasma proteinase inhibitors (serpins) and alpha 2-macroglobulin was tested. In addition, enhancement of the vascular permeability reaction in guinea pig skin by Df-proteinase was examined in vivo. These experiments showed that Df-proteinase could activate all the steps of the kinin-generating cascade, i.e., HF, PK and HMWK, and that Df-proteinase retained proteolytic activity even in the presence of an excess amount of endogenous proteinase inhibitors in plasma. We also found that the marked enhancement of the vascular permeability reaction was induced by Df-proteinase via the activation of the kinin-generating cascade without the release of histamine. From these results, we conclude that the proteinase of the house dust mite, Df-proteinase, has the potential to generate bradykinin and that the presence of this proteinase in biological systems would exacerbate inflammatory reactions in some pathological conditions.     

A biotinylated peptide,BP21, as a novel potent anti‐anaphylactic agent targeting platelet‐activating factor

Platelet‐activating factor (PAF) is an important mediator of anaphylaxis and is therefore an anti‐anaphylactic drug target. We recently reported that synthetic N‐terminally biotinylated peptides (BP4‐BP29) inhibit PAF by directly interacting with PAF and its metabolite/precursor lyso‐PAF. In this study, we investigated whether the biotinylated peptides can inhibit anaphylactic reactions in vivo. In mouse models of anaphylaxis, one of the peptides, BP21, markedly and dose‐dependently inhibited hypothermia with a maximum dose–response within 30 min after administration, even at doses 20 times lesser than doses of the known PAF antagonist CV‐3988. In contrast, the anti‐hypothermic effect of BGP21, in which the Tyr‐Lys‐Asp‐Gly sequence in BP21 was modified to a Gly‐Gly‐Gly‐Gly sequence, was less than that of BP21. The alanine scanning and shuffling the amino acid residues of BP4 (Tyr‐Lys‐Asp‐Gly) demonstrated that the Tyr‐Lys‐Asp‐Gly consensus sequence is important for the inhibitory effect of the peptide on hypothermia. BP21 also suppressed vascular permeability during anaphylaxis with a maximum dose–response within 30 min of administration. In a rat model of hind paw oedema, BP21 significantly inhibited the oedema induced by PAF but not that induced by the other pro‐inflammatory mediators, such as histamine, serotonin, and bradykinin. Tryptophan fluorescence measurements showed that BP21 interacted with PAF, but not with histamine, serotonin, or bradykinin. In contrast, BGP21 did not interact with PAF. These results suggest that biotinylated peptides, especially BP21, can specifically and markedly inhibit anaphylactic reactions in vivo and that this involves direct interaction of its Tyr‐Lys‐Asp‐Gly region with PAF. Therefore, a biotinylated peptide, BP21, can be used as novel potential anti‐anaphylactic drugs targeting PAF. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

Modulation of cutaneous inflammation by angiotensin-converting enzyme

Cutaneous neurogenic inflammation is a complex biological response of the host immune system to noxious stimuli. Present evidence suggests that zinc metalloproteases may play an important role in the regulation of neurogenic inflammation by controlling the local availability of neuropeptides, such as substance P (SP), that are capable of initiating or amplifying cutaneous inflammation after release from sensory nerves. To address the hypothesis that the dipeptidyl carboxypeptidase angiotensin-converting enzyme (ACE) is capable of modulating skin inflammation, we have analyzed murine allergic contact dermatitis (ACD) and irritant contact dermatitis (ICD) using wild-type C57BL/6J (ACE(+/+)) or genetically engineered mice with a heterozygous deletion of somatic ACE (ACE(+/-)). In 2,4-dinitro-1-fluorobenzene-sensitized ACE(+/-) mice, ACD was significantly augmented in comparison to ACE(+/+) controls as determined by the degree of ear swelling after exposure to hapten. Likewise, systemic treatment of ACE(+/+) mice with the ACE inhibitor captopril before sensitization or elicitation of ACD significantly augmented the ACD response. In contrast, local damage and neuropeptide depletion of sensory nerves following capsaicin, injection of a bradykinin B(2), or a SP receptor antagonist before sensitization significantly inhibited the augmented effector phase of ACD in mice with functionally absent ACE. However, in contrast to ACD, the response to the irritant croton oil was not significantly altered in ACE(+/-) compared with ACE(+/+) mice. Thus, ACE by degrading bradykinin and SP significantly controls cutaneous inflammatory responses to allergens but not to irritants, which may explain the frequently observed exacerbation of inflammatory skin disease in patients under medication with ACE inhibitors.     

Role of the protease in the permeability enhancement by Vibrio vulnificus

The protease produced by Vibrio vulnificus enhances vascular permeability through histamine release from mast cells and activation of the plasma kallikrein-kinin system which generates bradykinin when injected into the dorsal skin. V. vulnificus living cells also enhanced vascular permeability within a few hours after the injection into the dorsal skin. The permeability-enhancing activity of living cells was greatly reduced by addition of soybean trypsin inhibitor, a specific inhibitor for plasma kallikrein-kinin system, or anti-protease IgG. Two protease-deficient mutants induced by nitrosoguanidine treatment had only one-tenth permeability-enhancing activity of a wild-type strain. These results indicate that V. vulnificus elaborates the protease in vivo and that the protease elaborated enhances vascular permeability through release of chemical mediators such as histamine and bradykinin and forms edema.     

Neurogenic inflammation, vascular permeability, and mast cells

Electrical stimulation (ES) of sensory nerves causes increased vascular permeability and vasodilatation, a process known as neurogenic inflammation. The purpose of this study was to assess the role of mast cells in neurogenic inflammation induced by ES of sensory nerves. ES of the rat saphenous nerve for 1, 3, 5, 15, or 30 min induced a 166 to 436% increase in the amount of 125I-albumin deposited in the skin. Through the initial 15 min of ES, the histamine content of the skin remained unchanged. However, 30 min of ES caused a 22.1% decrease in skin histamine (p less than 0.05). ES for 5 min followed by measurement of vascular permeability from 0 to 30 min thereafter resulted in maximal increases in 125I-albumin in the skin immediately after cessation of the pulse of ES. When skin histamine was measured at various intervals after a 5-min pulse of ES, no change in the histamine content was observed through the subsequent 30 min. When mast cell degranulation was assessed histologically, 5 min of ES failed to stimulate mast cell degranulation. However, 30 min of ES caused a significant increase in the proportion of degranulating mast cells. When draining venous plasma histamine was monitored before, during and after ES, no change in plasma histamine was observed. In contrast, the intradermal injection of 5 micrograms of compound 48/80 produced a significant increase in plasma histamine. In order to examine the possibility that histamine might be released but remain in the skin after ES, skin "blisters" were developed by intradermal injections of saline. There was a significant increase in the amount of 125I-albumin extravasated into blister fluid measured after 3, 5, and 10 min of ES and a significant increase in histamine after 5 or 10 min. Therefore, prolonged ES of sensory nerves can cause mast cell degranulation. However, ES causes increased vascular permeability at times when no mast cell activation can be observed. These data suggest that the initial phases of neurogenic inflammation are independent of mast cell activation.     

Inhibitory effects of galanin on evoked [Ca2+]i responses in cultured myenteric neurons

Galanin modulates gastrointestinal motility by inhibiting the release of ACh from enteric neurons. It is, however, not known whether galanin also inhibits neuronal cholinergic transmission postsynaptically and whether galanin also reduces the action of other excitatory neurotransmitters. The aim of the present study was thus to investigate the effect of galanin on the evoked intracellular Ca(2+) concentration ([Ca(2+)](i)) responses in myenteric neurons. Cultured myenteric neurons from small intestine of adult guinea pigs were loaded with the Ca(2+) indicator fluo-3 AM, and the [Ca(2+)](i) responses following the application of different stimuli were quantified by confocal microscopy and expressed as a percentage of the response to high-K(+) solution (75 mM). Trains of electrical pulses (2 s, 10 Hz) were applied to stimulate the neuronal fibers before and after a 30-s superfusion with galanin (10(-6) M). Substance P (SP), 5-HT, 1,1-dimethyl-4-phenyl-piperazinium iodide (DMPP), and carbachol were used as direct postsynaptic stimuli (10(-5) M, 30 s) and were applied alone or after galanin perfusion. Galanin significantly reduced the responses induced by electrical fiber stimulation (43 +/- 2 to 35 +/- 3%, P = 0.01), SP (15.4 +/- 1 to 8.0 +/- 0.3%, P < 0.01), and 5-HT (26 +/- 2 to 21.4 +/- 1.5%, P < 0.05). On the contrary, galanin did not affect the responses induced by local application of DMPP and carbachol. We conclude that in cultured myenteric neurons, galanin inhibits the excitatory responses induced by electrical stimulation, SP, and 5-HT. Finally, the inhibitory effect of galanin on electrical stimulation, but not on DMPP- and carbachol-induced responses, suggests that, at least for the cholinergic component, galanin acts at the presynaptic level.     

A study of chemically induced acute inflammation in the skin of the rat

Oedema due to application of benzene to the skin was reduced following prior sensory denervation and in animals systemically pre-treated with capsaicine (which is known to confer resistance to chemical irritants) or compound 48/80 (which depletes the body of mast cells). Increased degranulation of mast cells in the benzene-treated skin was unaffected by denervation but did not occur after treatment with capsaicine. Antidromic stimulation of a cutaneous nerve caused oedema and degranulation of mast cells, both of which were less severe than the corresponding effects of topically applied benzene. These effects were completely prevented by prior treatment with capsaicine and the oedema was less severe in 48/80-treated rats. Hence, the presence of mast cells was necessary for full development of the effects of antidromic stimulation. These observations indicate that axon reflexes in sensory fibres contribute to, but are not entirely responsible for, the development of oedema in chemically irritated skin. The prophylactic action of capsaicine may be due to the prevention of degranulation of mast cells rather than to a direct effect on cutaneous nerve endings. These conclusions are embodied in an hypothesis purporting to explain the involvement of axon reflexes, mast cells and various humoral mediators in chemically induced acute inflammation.     

Indirect mechanism of histamine-induced nociception in temporomandibular joint of rats

A considerable amount of evidence suggests that temporomandibular joint (TMJ) pain associated with temporomandibular disorder results, at least in part, from an inflammatory episode. Although histamine can cause pain, it is not clear whether this mediator induces nociception in the TMJ. In this study, we investigated the contribution of endogenous histamine to formalin-induced nociception in the TMJ of rats. We also investigated whether the administration of histamine induces nociception in the TMJ and, if so, whether this effect is mediated by an indirect action on primary afferent nociceptors. Local administration of the H1-receptor antagonist pyrilamine prevented formalin-induced nociception in the TMJ in a dose-dependent manner. Local administration of histamine (250 microg) in the TMJ induced nociceptive behavior that was inhibited by co-administration of the lidocaine N-ethyl bromide quaternary salt QX-314 (2%) or the selective H1-receptor antagonist pyrilamine (400 microg). Nociception induced by histamine was also inhibited by pre-treatment with sodium cromoglycate (800 microg) and by co-administration of the 5-HT(3) receptor antagonist tropisetron (400 mug), while pyrilamine (400 mug) did not inhibit nociception induced by 5-hydroxytryptamine (5-HT, 250 microg) in the TMJ. Furthermore, histamine, in a dose that did not induce nociception by itself, strongly enhanced 5-HT-induced nociception. Finally, the administration of a sub-threshold dose of 5-HT (100 microg), but not of histamine (100 microg), elicited nociception in the TMJ previously challenged with the inflammatory agent carrageenan (100 microg). In conclusion, these data suggest that histamine induces TMJ nociception by an indirect mechanism involving endogenous release of 5-HT and activation of 5-HT(3) receptors on sensory afferents. It is proposed that histamine activates the H1 receptor to induce the release of 5-HT which depolarizes the nociceptor by activating 5-HT(3) receptor.     

Effects of putative galanin antagonists M35 and C7 on rat exocrine pancreas.

Galanin is a neuropeptide having a wide range of biological actions. Recently selective galanin receptor antagonists such as M35 [galanin(1-12)-Pro-bradykinin(2-9)-amide] and C7 [galanin(1-12)-Pro-spantide-amide] have been described. These antagonists have blocked the actions of galanin on flexor reflex, glucose-induced insulin secretion, and acetyicholine release from hippocampus. Our present aim was to investigate whether M35 and C7 can affect galanin-induced inhibition of pancreatic enzyme secretion in rats. Pancreatic enzyme secretion was studied in urethane-anesthetized rats supplied with jugular vein catheter and pancreatic cannula. Amylase secretion evoked by submaximal CCK-8 stimulation was inhibited dose-dependently by galanin in anesthetized rats. Surprisingly, neither M35 nor C7 was able to inhibit the responses of the exocrine pancreas to galanin. However, both putative galanin receptor antagonists behaved as agonists in our experimental models. Our data suggest that the effects of galanin on pancreatic enzyme secretion are not mediated by M35- or C7-sensitive galanin receptors. Therefore, these galanin receptors are different from those described in the central nervous system.     

Isoprostanes induce plasma extravasation in rat skin

Isoprostane E2 (8-iso PGE) and isoprostane F2 alpha (8-iso PGF) contribute to numerous vascular, proinflammatory, and nociceptive functions. The underlying mechanisms for many of their actions are still under investigation. We examined the ability of isoprostanes to promote cutaneous inflammation using the Evan's blue dye method. Our data show that 4 micrograms subcutaneously (s.c.) injected 8-iso PGE or 8-iso PGF induced plasma extravasation in glabrous rat skin. Dye extravasation was also elicited in hairy skin after injections of 8-iso PGE, but not after 8-iso PGF. Isoprostane-evoked dye extravasation can be reduced by pretreatment with both the S+ and R- isomers of the cyclooxygenase (COX)-inhibitor ibuprofen (30 mg/kg intraperitoneally), indicating perhaps a nonspecific inhibition; pretreatment with ketorolac (1 and 10 mg/kg i.v.) was without effect. Unlike isoprostane-induced cutaneous nociceptor sensitization, which is blocked in a stereospecific and dose-dependent manner by COX-inhibitors, the effect of these drugs on isoprostane-induced cutaneous plasma extravasation is less consistent. We conclude that at least a large component of the isoprostane effect on cutaneous plasma extravasation is COX-independent.