Jeffrey A. Doebler

Protective effect of diazepam pretreatment on soman-induced brain lesion formation.

Histopathological analyses of brains of rats receiving a single 0.9 LD50 injection of soman, a potent anticholinesterase neurotoxin, revealed massive widespread lesions in the cerebral cortex and thalamus 4 weeks post-injection. Such lesions were not evidenced in rats receiving diazepam (2.2 mg/kg, i.m.) 10 min prior to soman treatment. Thus, anticonvulsant antidotes may aid in preventing extensive or permanent brain damage in rats surviving near-lethal soman dosages.

The distribution of [125I]ricin in mice following aerosol inhalation exposure

Studies were conducted to examine the uptake and redistribution of [125I]ricin from the lungs of mice following nose-only aerosol inhalation exposure. Radiolabelled contents were measured in lung and various extra-pulmonary tissues 15 min through 30 h following 10 min aerosol exposures. Pharmacokinetic analyses were performed on whole-organ data obtained for lungs, stomach, liver and spleen. Radioactivity within the lungs, maximal at 15 min post-exposure, was eliminated in a biexponential fashion with a long beta half-life (approximately 40 h). Large amounts of radiolabel were also found within the gastrointestinal tract. Radiolabel within the stomach exhibited an absorption phase and two-compartment elimination. Radiolabel content of many other tissues, including known accumulation sites for intravenously administered toxin, was significantly (p < 0.05) increased (relative to 15 min post-exposure) in association with the early elimination of radiolabel from the lungs, but levels in these tissues were very low and did not increase after 4 h post-exposure. The only exception was our sample of trachea, which showed delayed elevations in radiolabel (peak at 24 h); this pattern was attributable to the contained thyroid (not removed at necropsy) and its trapping of free [125I] released upon tissue [125I]ricin degradation. The overall data indicate that ricin administered by aerosol inhalation is delivered to both respiratory and gastrointestinal tracts; however, it is not extensively transported from either tract to other potential target sites. Ricin delivered to the lungs is primarily sequestered within the lungs until degradation. Only small amounts of ricin delivered to the gastrointestinal tract are absorbed into the circulation.

Interferometric analysis of intrasection and intersection thickness variability associated with cryostat microtomy

SummaryMach-Zehnder interferometric measurements were used to assess the extent of section thickness variability (inter- and intrasection) associated with cryostat microtomy of adrenal sections over a typical working range of 10–20 μm. Sections were obtained using a Brights Cambridge rocking type and a Damon rotary type cryostat microtome to allow comparative analyses. The effective thickness of tissue sections after being mounted onto slides by flash drying was reduced by 90% relative to microtome section thickness setting. A linear relationship between measured thickness and microtome setting was obtained with both instruments. Thickness variability between replicate sections over the range of microtome settings approximated 11% for the rocking microtome and 5% with the rotary microtome. Average intrasection variability was found to be 7% for rocking microtome sections and 4% for sections obtained with the rotary microtome. However, this variability is a negligible source of error in cytophotometric analyses, providing replicate sections are used and an adequate number of measurements are made on mask-delimited individual cells or tissue specimen areas.

Brain neuronal RNA metabolism during acute soman toxication: Effects of antidotal pretreatments

Effects of various antidotal treatments on neuronal RNA contents and on soman induced RNA and acetylcholinesterase (AChE) depletion were monitored using quantitative cytochemical techniques. In rats treated only with antidotes, atropine depressed whereas pralidoxime (2-PAM) elevated RNA contents of both caudate and cerebrocortical (Layer V) neurons. Soman produced a virtually complete inhibition of AChE activity and a moderate decline in neuronal RNA contents. Atropine pretreatment partially restored neuronal RNA levels. Atropine+2-PAM prophylaxis eventuated in a complete restoration of RNA levels but no reactivation of AChE. Addition of physostigmine to the atropine +2-PAM treatment regimen resulted in appreciable AChE reactivation but reduced RNA levels. The overall data indicate that: (1) soman-induced neuronal RNA depletion can be completely reversed by antidotal pretreatment; (2) no precise relationship exists between the extents of antidote-induced restoration of RNA and AChE levels; and (3) 2-PAM exerts marked effects on the brain neuronal network which are unrelated to AChE reactivation. It is postulated that effects of soman and antidotes on neuronal RNA metabolism may signify alterations in acetylcholine (ACh) sensitivity and that pharmacologic manipulation of ACh responsiveness during organophosphate cholinesterase poisoning may be a mechanism for additional therapeutic intervention.

Scanning cytophotometric analysis of brain neuronal nuclear chromatin changes in acute T-2 toxin-treated rats.

Male Sprague-Dawley rats (200 g) were injected intraperitoneally with T-2 toxin, a trichothecene mycotoxin protein synthesis inhibitor, at dosages of 0.75, 1.0, 1.5, and 6.0 mg/kg (1 LD50 = 0.9 mg/kg) before decapitation at 8-hr postexposure. Correlative data were obtained on changes in physicochemical properties of nuclear chromatin, chromatin dispersion, and nuclear volume of cerebrocortical (layer III) and striatal neurons using Feulgen-DNA (F-DNA) cytophotometry and ocular filar micrometry. Decreased lability of neurons to F-DNA acid hydrolysis (reduced F-DNA yield), nuclear shrinkage, and chromatin aggregation (decreased chromophore area) were used as indices of suppression of genomic template activity, i.e., neuronal nuclear functioning. Conversely, increased F-DNA yield, chromophore area, and nuclear volume signify enhanced neuronal activation. At 8 hr following T-2 toxin exposure, cerebrocortical and striatal neurons exhibited a dose-dependent decrease in F-DNA hydrolyzability, i.e., impaired chromatin activity, and increases in both chromatin dispersion and nuclear volume. Microscopic observation revealed no gross evidence of T-2 induced neurotoxicity. These data indicate that T-2 toxin elicits both neurochemical injury and adaptive or compensatory processes simultaneously. The toxicological importance of observed nuclear alterations and the role of impairments in central nervous system metabolism in acute T-2 toxicity remain to be ascertained.

Nuclear chromatin changes in hepatocytes of soman treated rats.

Cytochemical and morphometric indices of DNA metabolism and nuclear transcriptional-translational capabilities were used to monitor liver responses in Sprague-Dawley X Wistar rats subcutaneously injected with 0.9 LD50 soman, a highly toxic acetylcholinesterase-inhibiting organophosphate. Thirty minutes post-soman the following were evident: (1) increased polyploidization; (2) expansion of the nuclear envelope; and (3) elevated deoxyribonucleoprotein (DNP) complex lability to acid hydrolysis. Nuclear changes were accompanied by cytoplasmic correlates of impaired hepatocyte function, i.e., vacuolation and depressed basophilia. The overall data suggest that with acute soman toxication there are concomitant adaptive and maladaptive responses occurring within liver parenchymal elements. It is postulated that nuclear changes represent an early proliferative response and DNP activation to enhance detoxification capabilities, whereas cytoplasmic changes reflect the disruption of normal function and hepatotoxic injury.

Ribonucleic acid changes in medial cells in evans blue positive regions of the dog aorta

Abstract Evidence is presented supporting the feasibility of using cytophotometric analysis of cellular azure B-RNA dye binding as a cytochemical marker of metabolic alterations in medial smooth muscle cells underlying aortic areas having spontaneously occurring increased uptake of Evans blue dye. Focal areas of enhanced permeability or intra-aortic macromolecular accumulation (demarcated by in vivo uptake of Evans blue dye) exhibited 20–40% higher extents of azure B staining in intimal, medial, and adventitial compartments when compared to corresponding compartments in dye-impermeable regions. No discernible differences were evidenced in deoxyribonucleic acid levels (using Feulgen-DNA cytophotometry) or in the histological appearance (using conventional staining) between Evans blue-positive and negative aortic specimens. The overall data suggest that (1) focal differences in cellular azurophilia are attributable to differences in rates of uptake or accumulation of plasma constituents in Evans blue-permeable and impermeable aortic regions, and (2) the permeability-associated increase in azurophilia is due to an increase in ribosomes and reflects a compensatory activation of metabolic processes in response to an increased uptake and transmural transport of plasma macromolecules.

Brain neuronal RNA metabolism during sustained low-level soman toxication

Quantitative azure B-RNA cytophotometry was used to monitor metabolic responses of cholinergic elements of the rat brain during sustained low-level administration of soman (0.25-0.50 LD50, sc). RNA contents of caudate and cerebrocortical (Layers III and V) neurons were measured 60 min following 1-5 soman dosages given at 24 h intervals. Marked and progressive RNA depletion was evidenced after 1-4 soman injections, whereas partial or complete restitution of RNA levels was observed following the fifth injection. These data indicate that repetitive soman toxication is associated with metabolic correlates of impaired rather than accentuated activation of CNS cholinergic systems, and that tolerance is developed to CNS actions of the agent. It is postulated that impaired neuronal activation is related to soman or ACh-induced transmission block, and that the same adaptive processes responsible for recovery during acute poisoning may underlie the development of tolerance during repetitive administration of organophosphates.

Quantitative cytophotometric analyses of mesenteric mast cell granulation in acute soman intoxicated rats

Effects of the organophosphate neurotoxin soman on rat mesenteric mast cell granule content were determined using scanning-integrating microdensitometric analysis of individual cell metachromasia. Mast cell degranulation was evidenced both with sublethal (0.5 LD50) and lethal (1.5 LD50) dosages and as early as 3–10 min post-injection. These data indicate a possible contribution of mast cell autacoids in the genesis of organophosphate-induced respiratory and circulatory collapse.

Brain neuronal chromatin responses in acute soman intoxicated rats

Male Sprague-Dawley rats (200 g) were injected subcutaneously with soman, a potent neuronal acetylcholinesterase (AChE) inhibitor, at doses of 0.5, 0.8 and 1.0 LD50 (1 LD50=135 μg/kg) before decapitation at 1 and 24 h post-exposure. Correlative data were obtained on the severity of brain AChE inactivation and physicochemical changes in nuclear chromatin of cerebrocortical (layer V) and striatal neurons using Feulgen-DNA (F-DNA) cytophotometry and ocular filar micrometry. Decreased lability of neurons to F-DNA acid hydrolysis (reduced F-DNA yield), nuclear shrinkage and chromatin aggregation (decreased chromophore area) were used as indices of suppression of genomic template activity; conversely, increases in F-DNA yield and chromophore area signify enhanced neuroexcitation. At 1 hr post-soman there was a dose-dependent inactivation of AChE with a moderate increase in chromatin activation, i.e., nuclear hypertrophy and chromatin dispersion. At 24 hr post-soman there was a partial restoration of AChE activity, notably in striatal neurons, with a suppression in chromatin template activity. These data indicate that actions of soman on neuronal functioning are time-dependent. The absence of any dose-related neuronal chromatin changes may signify existence of non-cholinergic mediated events.