Antidote effect of sodium fluoride against organophosphate poisoning in mice

Pretreatment of mice with atropine (17.4 mg/kg) + NaF (5 or 15 mg/kg) had a significant antidotal effect over atropine alone against the lethality produced by soman and sarin. Atropine + NaF (15 mg/kg) was effective against tabun, whereas the lower dose of NaF was not. An effect of NaF on organophosphate inhibited acetylcholinesterase could not account for the antidotal action of NaF. NaF had no effect on liver somanase activity but inhibited aliesterase activity. Aliesterase activity in NaF pretreated somanpoisoned mice was significantly (p < 0.05) higher than in those receiving atropine alone. In CBDP-pretreated mice NaF did not significantly attenuate the toxicity of soman. It is hypothesized that the antidotal effect of NaF versus organophosphate poisoning is due to its antidesensitizing action at nicotinic receptors in the neuromuscular junction and/or sympathetic ganglia in addition to the proposed increased hydrolysis of sarin and direct detoxification of tabun.     

Non-opioid analgesia of the neuropeptide, neo-kyotorphin and possible mediation by inhibition of GABA release in the mouse brain

The novel neuropeptide, neo-kyotorphin, produced a naloxone-resistant analgesia in the tail pinch test when given (IC) to mice. Pretreatments with implantation of a morphine pellet or with phentolamine (10 micrograms IT) or with reserpine (10 mg/kg SC) did not attenuate this analgesia, yet the analgesia was antagonized by GABA mimetics, such as muscimol (0.1 microgram IC), nipecotic acid (100 mg/kg IP). Neo-kyotorphin inhibited the Ca2+-dependent and depolarization-evoked release of 3H-GABA, from crude synaptosomes of the lower brain stem of rats. These findings suggest that inhibition of GABA in the brain may in part be involved in neo-kyotorphin-induced analgesia.     

Effect of soman (pinacolyl methylphosphonofluoridate) on the blood levels of corticosterone and adrenocorticotropin in mice

Mice were poisoned by an extremely toxic organophosphate anticholinesterase soman (pinacolyl methylphosphonofluoridate), 50 or 100 micrograms/kg at 1000, and the serum concentrations of corticosterone were determined fluorometrically at 3-h intervals for at least 24 h. The lower soman dose (50 micrograms/kg) produced a modest increase in serum corticosterone concentrations but by 24 h the levels were not significantly different from control. Following the higher soman dose (100 micrograms/kg) the serum corticosterone levels were elevated significantly (p less than 0.05), for at least 27 h. However, ACTH concentrations were not elevated. It is possible that the elevated levels of corticosterone were due to a reduced metabolism and excretion of corticosterone resulting from the intense hypothermia, following soman poisoning which may change cardiac output and organ (liver and kidney) perfusion and not due to an enhanced release from the adrenal gland.     

Effect of soman on schedule-controlled behavior and brain acetylcholinesterase in rats

Rats were trained to press a lever under a multiple fixed-ratio 25 fixed-interval 50-second (FR25 FI50-sec) schedule of food reinforcement. Soman, 70-90 micrograms/kg, s.c., suppressed response rates in both components, with a slightly greater effect in the FI schedule. The pattern of responding under the FI schedule, however, was maintained until lever-pressing was nearly completely suppressed. At the highest doses, soman occasionally caused tremors or mild tonic seizures with hindlimb abduction. The suppression of response rate was correlated with inhibition of acetylcholinesterase (AChE) in all brain regions examined: cortex, striatum, hippocampus, hypothalamus and brainstem. Cortical AChE was inhibited to the highest degree, while striatal AChE was most resistant to inhibition by soman.     

Opioid antinociception and positive reinforcement are mediated by different types of opioid receptors

Fentanyl (FEN) and diprenorphine's (DIPR) potentials for analgesia and reinforcement were assayed using rats. Analgesia was measured by the classic tail-flick test. The test germane to opioid reinforcement involved measuring pressing rates for direct electrical stimulation of the lateral hypothalamus and ventral tegmental area. FEN, as does morphine and heroin, produced strong analgesia and enhanced pressing rates for brain stimulation. DIPR produced no analgesia and antagonized FEN's analgesia. DIPR, at doses antagonizing FEN's analgesia, enhanced pressing for brain stimulation. DIPR's enhancement of pressing was antagonized by naloxone (100 micrograms/kg). When FEN and DIPR were given concurrently, pressing for brain stimulation was not reduced and was greater than after FEN alone was given. These data support a conclusion that different types of receptors are associated with opioid analgesia and reinforcement.     

Neuropathy target esterase in hens after sarin and soman

To estimate the potential of small doses of sarin (types I and II) and soman to cause delayed neuropathic effects, 400, 200, 61, and 0 micrograms/kg of sarin-I, 280, 140, 70, and 0 micrograms/kg of sarin-II, and 14.2, 7.1, 3.5, and 0 micrograms/kg of soman by gavage were compared with 510 mg/kg tri-o-cresyl phosphate (TOCP) in 14- to 18-month-old SPF white leghorn hens (4/dose) protected with atropine (100 mg/kg). The neuropathy target esterase (NTE) activity 24 hr after dosing was determined in brain, spinal cord, and lymphocytes and in plasma and brain for cholinesterase and carboxylesterase. None of the compounds showed statistically significant NTE decreases. Sarin-II showed a dose-related trend in the lymphocyte NTE (to 33% of control at 280 micrograms/kg), suggesting that longer exposure to lower doses might cause a cumulative neurotoxic insult. All of the agents decreased the activity of plasma and brain cholinesterase and carboxylesterase. Using more than 70% inhibition of brain NTE as a biochemical predictor of delayed neuropathy, sarin and soman appear unable to cause delayed neuropathy at nonlethal doses within this protocol.     

Effects of morphine on hexamethonium-sensitive and -resistant excitatory responses of stomach to stimulation of vagal trunk in cats

Electrical stimulation of the vagal trunk with 10 Hz in frequency, 3 ms in duration and 15 volt in intensity for 10 s in cats produced an excitatory response of the stomach and the response was composed of two phases, an initial rapid excitation during stimulation period and the late multi-peak response after stimulation period. The initial response was inhibited by the administrations of hexamethonium (10 mg/kg, i.v.) and atropine (100 micrograms/kg, i.v.). The late response was not inhibited by hexamethonium but was inhibited by atropine (100 micrograms/kg, i.v.). The hexamethonium-sensitive initial excitation was not affected by the administration of morphine and gamma-aminobutyric acid (GABA). On the other hand, the hexamethonium-resistant late response was attenuated by the treatment with morphine (1 to 10 mg/kg, i.v.) and GABA (100 to 500 micrograms/kg, i.v.). Such inhibitory actions of morphine and GABA on the late response were antagonized by picrotoxin. From these results, it was concluded that morphine might inhibit specifically the hexamethonium-resistant late excitatory response of the stomach without affecting the hexamethonium-sensitive initial excitatory response and the inhibitory effect of morphine on the late response of stomach might be due to action of GABA released from the intramural neurons of gastric walls in cats.     

Evidence for antagonistic activity of endothelin for clonidine induced hypotension and bradycardia.

Effect of endothelin (ET) on clonidine induced cardiovascular effects was studied in male Sprague-Dawley rats. Clonidine (75 micrograms/kg, iv) produced significant decrease in blood pressure and heart rate. ET-1 (50 ng/kg, iv) pretreatment completely antagonized the hypotension and bradycardia induced by clonidine. ET-2 (50 ng/kg, iv) and ET-3 (50 ng/kg, iv) had similar antagonistic effect on clonidine induced hypotension and bradycardia. The antagonistic effect of ET lasted for several hours, however, 4 hours after ET pretreatment only partial blockade of clonidine induced hypotension and bradycardia was observed. This indicated that the antagonistic effect of ET was reversible. Initial hypertensive response induced by high dose of clonidine (750 micrograms/kg, iv) could not be antagonized by ET-1, ET-2 or ET-3, while phenoxybenzamine, an alpha adrenoceptor antagonist, blocked the hypertensive response of clonidine. Thus, ET has no antagonistic effect on the initial hypertensive response but antagonizes the hypotensive and bradycardic effect induced by clonidine. Clonidine induced hypotension and bradycardia are mediated through central alpha 2 adrenoceptors while hypertension is mediated through peripheral alpha 2 adrenoceptors. It is concluded that central alpha 2 adrenoceptors are different from peripheral alpha 2 adrenoceptors and ET antagonizes the effect of clonidine only on central alpha 2 adrenoceptors but has no antagonistic activity on peripheral alpha 2 adrenoceptors.     

Inhibitory effects of beta-alanine on the vagal efferent and afferent excitatory responses of the stomach to stimulation of vagal trunk in cats.

The effects of beta-alanine on the electrically evoked vagal efferent (hexamethonium-sensitive initial excitatory response) and afferent (hexamethonium-resistant delayed excitatory response) responses of the cat stomach were studied. beta-alanine (30 to 300 micrograms/kg, i.v.) dose-dependently inhibited both the efferent and afferent response. The IC50 values of beta-alanine on the efferent and afferent response were 296 +/- 65 micrograms/kg and 128 +/- 35 microgram/kg, respectively. Maximal inhibitory effects of beta-alanine (300 micrograms/kg, i.v.) appeared about 1 hr after the injection. Glycine and taurine (100 to 10,000 micrograms/kg) did not affect these responses. Treatment with hexamethonium (10 mg/kg, i.v.) prevented the efferent response, but augmented the afferent response. The treatment with hexamethonium abolished the inhibitory effect of beta-alanine on the afferent response. Both picrotoxin (100 and 500 micrograms/kg, i.v.) and bicuculline (2000 micrograms/kg, i.v.) antagonized the inhibitory effects of beta-alanine on the vagal efferent and afferent responses of the stomach. The present experiments clearly demonstrated that beta-alanine inhibited both the vagal efferent and afferent excitatory responses of stomach to electrical stimulation of vagal trunk in cats.     

Effect of cyclosporin A on human lymphocyte responses in vitro. III. CsA inhibits the production of T lymphocyte growth factors in secondary mixed lymphocyte responses but does not inhibit the response of primed lymphocytes to TCGF

The mechanism whereby Cyclosporin A (CsA) inhibits secondary mixed lymphocyte responses was assessed. CsA added to secondary MLR cultures inhibited proliferation and induction of cytolytic lymphocyte activity. This inhibition was found to be associated with the inhibition of T lymphocyte stimulating growth factor(s) (TCGF) production in the supernatants of secondary MLR cultures. As little as 1.0 micrograms/ml of CsA added to secondary MLR cultures resulted in no measurable TCGF activity. In contrast, moderate doses of CsA (1.0, 2.5 micrograms/ml), which completely inhibited the secondary MLR response to alloantigen, did not inhibit the proliferative and CML response of alloantigen-primed lymphocytes to these stimulating growth factors. Even at high doses of CsA (20 micrograms/ml), substantial levels of proliferation (50% of control response) and CML induction (60% of control response) were observed when the primed cells were exposed to secondary MLR supernatants containing TCGF activity. It was concluded that inhibition of secondary mixed lymphocyte responses by CsA may be due in part to the inhibition of TCGF production rather than the inhibition of the effect of TCGF on mature cytotoxic T lymphocytes.     

Partial reversal of behavioral action of the agonist D-Trp-6-LH-RH by naloxone in mice

The effects of the superactive agonist analog D-Trp-6-LH-RH were investigated in several neuropharmacological tests: inhibition of picrotoxin-induced seizures, open-field behavior, hot-plate and tail-flick tests, assessment of catalepsy and apomorphine-induced cage-climbing. In most tests, D-Trp-6-LH-RH was administered subcutaneously (sc.) at the dose of 100 micrograms/kg. The opiate involvement in the peptide action was checked by using naloxone HCl (NX) in a dose of 1 mg/kg intraperitoneally (ip.), with the exception of the analgesic tests where the dose was 0.5 mg/kg. The analog significantly suppressed the open-field parameters of ambulation, rearing and grooming; except for grooming, these actions were fully antagonized by NX. Similarly, NX pretreatment restored to the control levels the latencies of seizure parameters increased by D-Trp-6-LH-RH. The hot-plate latencies did not change after pretreatment with NX but the opiate antagonist was fully able to antagonize the analgesic effect of the peptide in the tail-flick test. The cataleptogenic effect and the inhibition of apomorphine-induced cage-climbing demonstrated after D-Trp-LH-RH were not antagonized by NX.     

Examination of the Role of Central Cholinergic Mechanisms in the Therapeutic Effects of HI-6 in Organophosphate Poisoning

Abstract: In atropine-pretreated rats, HI-6 (125 mg/kg i.p.) raised the LD₅₀ of Soman (subcutaneous) 5.7 times. Addition of HI-6 (25 μg i.c. v.) failed to enhance this protection further. HI-6 (intraperitoneal) also protected animals from intracerebroventricular Soman. HI-6, administered intracerebroventricularly either alone or in combination with intraperitoneal HI-6, failed to increase protection, nor did it reactivate Soman-inhibited acetylcholinesterase (AChE) in several brain areas. HI-6 (125 or 62.5 mg/kg i.p.) protected rats from Sarin lethality, but only the higher dose significantly altered the brain AChE activity. Furthermore, HI-6 (intraperitoneal) failed to block the Soman-induced increase in acetylcholine (ACh) or choline (Ch) levels in any of the brain areas examined. These data indicate that HI-6 is a very beneficial therapy against Soman, but that no definitive central anticholinergic activity of the compound could be found to explain its protective effects. It is possible that HI-6 acts by noncholinergic central mechanisms, or that it produces its beneficial effects outside the CNS. Furthermore, brain AChE activity does not appear to be indicative of protective effects of this oxime. ACh or Ch levels in this study were not good parameters to predict the outcome of Soman poisoning.     

Cholecystokinin stimulates neuronal receptors to produce contraction of the canine colon

The motor effects of cholecystokinin 26-33-amide (CCK octapeptide; CCK-OP) and several purported CCK receptor antagonists on canine colonic circular muscle were determined in pentobarbital anesthetized dogs. Intravenous injections of CCK-OP had no effect on colonic motility at doses that contracted the gallbladder, stomach and duodenum. CCK-OP delivered by intraarterial injection to a small segment of the proximal colon produced a dose related increase in colonic motility with one-half maximum response at 12 ng/Kg and maximum response at 50 ng/Kg. The effects of intraarterial injections of several established CCK-receptor antagonists on proximal colonic responses to intraarterial injections of CCK-OP were determined. Proglumide, 10 mg/Kg, did not produce colonic contractions itself, but antagonized CCK-OP-induced responses. Carbobenzyloxy (CBZ)-CCK27-32-amide antagonized CCK-OP-induced colonic responses and also had no effect on basal colonic motility (0.1-1 and 5 micrograms/Kg). Neither compound antagonized acetylcholine- induced colonic responses. Butoxycarbonyl (BOC)-CCK31-33-amide increased basal colonic motility, but did not alter CCK-OP-induced responses at doses of 0.1 and 0.2 mg/Kg. Dibutyryl-cGMP at a dose of 0.1 mg/Kg did not affect basal motility or CCK-OP-induced contractions. At a dose of 1.0 mg/kg it increased basal colonic motility but did not affect CCK-OP-induced contractions. Pentagastrin increased colonic motor activity only at a dose of 5 micrograms/Kg, i.a., a much higher dose than effective doses of CCK-OP. The mechanism of CCK-OP-induced colonic motor effects also was determined. Atropine sulfate, 100 micrograms/Kg, i.v. significantly reduced both intraarterial acetylcholine-and CCK-OP-induced maximum colonic contractions. Tetrodotoxin, at intravenous doses that completely block neuronal activity, did not affect maximum acetylcholine-induced contractions but practically eliminated maximum CCK-OP-induced maximum colonic responses. In conclusion, intraarterial CCK-OP produces circular muscle contraction of the canine proximal colon that is mediated by stimulation of specific CCK receptors which produce the release of acetylcholine from cholinergic enteric neurons. Proglumide and CBZ-CCK27-32-amide are effective CCK receptor antagonists at these colonic neuronal receptors.     

Peripheral biochemical marker for organophosphate-induced delayed neurotoxicity.

Neurotoxicesterase (NTE) activity was assayed in platelets of human and mice as well as in the brain of mice in vitro and in vivo. Mipafox, a well known organophosphate, to induce delayed neurotoxicity, at doses of 5, 10 and 15 mg/kg, subcutaneously, was used to examine the relationship between inhibition of brain and platelet NTE activity in mice. It was observed that the platelet NTE activity of mice was less than in humans. The optimum pH for both brain and platelet NTE of mice, and human platelets, was 8. The results indicate that mipafox produces a dose dependent inhibition of brain and platelet NTE activity in vivo and concentration dependent inhibition in vitro. It can be concluded that assay of platelet NTE can be a useful peripheral biochemical marker for organophosphate-induced delayed neurotoxicity.     

Characterization of alpha-adrenoceptors involved in central thermoregulation in rabbits

Intracerebroventricular (icv) injection of methyldopa induced body temperature changes in the rabbits. The dose of 100 micrograms/kg did not produce any significant change on body temperature whereas 250 micrograms/kg of the drug induced hyperthermia. Higher dose of 500 micrograms/kg produced initial hypothermia which was followed by hyperthermia. On further increase of the dose to 1 mg/kg, consistent hypothermia was evident. Prazosin, a specific post-synaptic alpha 1 adrenoceptor blocker, induced hypothermia whereas piperoxan (presynaptic alpha 2 antagonist) produced hyperthermia. The pretreatment with prazosin, blocked the hyperthermic response of methyldopa. The initial hypothermia by 500 micrograms/kg of methyldopa was also potentiated. The pretreatment with piperoxan completely blocked the hypothermia but had no effect on hyperthermic response of methyldopa. Pretreatment of rabbits with both prazosin and piperoxan completely blocked the hypothermia as well as hyperthermic response of methyldopa. Thus it appeared that both presynaptic alpha 2 and postsynaptic alpha 1 adrenoceptors are involved in central thermoregulation in rabbits.     

Acute Effects of Soman, Sarin, and Tabun on Microsomal and Cytosolic Components of the Calmodulin System in Rat Striatum

Two hours after administration of Soman (120 micrograms/kg, s.c.), Sarin (150 micrograms/kg, s.c.), or Tabun (240 micrograms/kg, s.c.), microsomes and cytosol were prepared from rat striata. Microsomal and cytosolic calmodulin (CaM) levels, microsomal adenylate and guanylate cyclase activities, protein kinase activities, and Ca2+ + Mg2+-ATPase activities were determined while cytosolic phosphodiesterase (PDE) activities were determined. CaM levels in both cell fractions were significantly increased by Soman and Sarin. Cyclic AMP-PDE and adenylate cyclase activities were decreased by Soman and Sarin. All three agents decreased activities of cyclic GMP-PDE and guanylate cyclase. Sarin and Tabun administration caused significant increases in microsomal protein kinase activity and none of the agents affected activity of divalent cation ATPases. The intensity of effects of the three organophosphates roughly paralleled their observed neurotoxic potencies. The results indicate that components of the CaM system are implicated as either causative or adaptive changes induced by these agents.     

Structural and mutational studies of organophosphorus hydrolase reveal a cryptic and functional allosteric-binding site

Organophosphorus hydrolase detoxifies a broad range of organophosphate pesticides and the chemical warfare agents (CWAs) sarin and VX. Previously, rational genetic engineering produced OPH variants with 30-fold enhancements in the hydrolysis of CWA and their analogs. One interesting variant (H254R) in which the histidine at position 254 was changed to an arginine showed a 4-fold increase in the hydrolysis of demetonS (VX analog), a 14-fold decrease with paraoxon (an insecticide), and a 183-fold decrease with DFP (sarin analog). The three-dimensional structure of this enzyme at 1.9A resolution with the inhibitor, diethyl 4-methylbenzylphosphonate (EBP), revealed that the inhibitor did not bind at the active site, but bound exclusively into a well-defined surface pocket 12 A away from the active site. This structural feature was accompanied by non-competitive inhibition of paraoxon hydrolysis by EBP with H254R, in contrast to the native enzyme, which showed competitive inhibition. These parallel structure-function characteristics identify a functional, allosteric site on the surface of this enzyme.     

Glucagon is an antagonist of morphine bradycardia and antinociception

Glucagon and its receptors have been identified within the mammalian brain, and their anatomical distribution correlates well with the distribution of opioid peptides and their receptors. To evaluate possible physiological interactions between these two peptidergic systems, we examined the effects of glucagon on two opioid responses - bradycardia and antinociception. Glucagon administered either intravenously (iv) (100-1000 micrograms/kg) or intracerebroventricularly (icv) (5 micrograms) significantly attenuated morphine-induced (200 micrograms/kg, iv) bradycardia without producing any alterations in cardiovascular parameters when given alone. Furthermore, glucagon did not antagonize the bradycardia produced by phenyldiguanide (10 micrograms/kg, iv), a non-opioid substance. Peripheral (1 mg/kg, iv) and central (5 micrograms, icv) glucagon pretreatment antagonized morphine-induced (7.5 mg/kg, intraperitoneal) antinociception by 67% and 86%, respectively, at 30 minutes (as determined by the hot plate test). Glucagon treatment alone at these doses did not alter baseline response latencies. In both cases, central injections of glucagon were more effective than iv injections in antagonizing morphine's effects. These findings demonstrate a central action for glucagon and provide the first evidence that this neuropeptide may function as an endogenous antagonist of opioid actions.     

Role of endogenous opioids in soman (pinacolyl methylphosphonofluoridate)-induced antinociception

The effect of soman poisoning on the levels of methionine enkephalin and beta-endorphin in mice and rats were determined. Soman poisoning produced no significant effect on methionine enkephalin levels in the striatum of rats or mice or beta-endorphin levels in the pituitary gland of mice. In rats beta-endorphin levels were significantly reduced 24 hr post soman poisoning, but returned to control levels by 48 hr. In vitro, the hydrolysis of leucine enkephalin by aminopeptidase was virtually complete by 30 min and found to be the major route of degradation. The release of TYR-GLY-GLY in the presence or absence of puromycin (10 microM) was found to be low (less than or equal to 2.0%). A minor effect on TYR release in the presence of GLY-GLY-PHE-MET (50 microM) was insignificant. Preincubation of mouse striatum homogenates with soman (1 or 10 microM) did not inhibit the hydrolysis of leucine enkephalin. These results suggest that the long term antinociception following soman exposure is not due to either altered concentration of endogenous opioid-like substances or inhibition of the enzymes responsible for their degradation.     

Effects of nitroglycerin and nitroprusside on the pulmonary hemorrhagic edema induced by cerebral compression and epinephrine

In vagotomized and pentobarbital-anesthetized rats, massive pulmonary hemorrhagic edema was produced by cerebral compression (CC) or an injection of epinephrine (EP) 0.25 mg/kg. The pulmonary changes were induced following severe Cushing reaction manifested by systemic hypertension. We determined the dose-effect relationship of nitroglycerin (NTG) and nitroprusside (NPS) on the changes in systemic arterial pressure and lung pathology. The drugs were given by iv infusion 5 min before CC or EP and continued throughout the experiment. NTG, 5 micrograms/kg/min, did not affect the pressor response and the pulmonary damage. In a dose of 10 micrograms/kg/min, the CC- and EP-induced changes were partially blocked. A dose of 20 micrograms/kg/min almost completely prevented the CC- and EP-induced pulmonary changes despite partial blockade of the pressor response. NPS exerted more potent effects than NTG on such changes. A dose of 5 micrograms/kg/min was capable of decreasing the pressor response by about 20% and the lung changes by about 50%. In a dose of 10 micrograms/kg/min, the pulmonary changes were almost completely prevented. The results suggest that vasodilators such as nitroglycerin and nitroprusside can block the pressor response and pulmonary pathology subsequent to CC or EP. The effects may be attributed to the ventricular unloading action of these vasodilators that decrease the preload and afterload of the heart. In this respect, nitroprusside is more potent than nitroglycerin.