Pathobiology of acute triethyltin intoxication

Chemically Induced Myelinopathies

The diverse, structurally unrelated chemicals that cause toxic myelinopathies have been investigated and can be categorized into two types of primary demyelinators. Some demyelinating chemicals seem to leave intact the myeli-nating cells (oligodendrocytes in the central nervous system and Schwann cells in the peripheral nervous system), while others damage the myelinating cells as well as the myelin. The significance between the two is that with the myelinating cells still in tact, repair of the myelin sheath can occur. However, if the myelinating cells are destroyed, repair and reversal of the neuropathy may not occur. Histologically, these chemicals produce an edema of the white matter of the brain, and in some cases the peripheral nervous system, that appears spongy by light microscopy. By electron microscopy, vacuoles can be seen in the myelin surrounding axons. These vacuoles are characterized as fluid-filled separations (splitting) of myelin lamellae at the intraperiod line. In some cases these vacuoles can degenerate further to full demyelination, affecting conduction through those axons. Regeneration of the myelin layers can occur, and in some cases occurs at the same time other axons are undergoing toxic demyelination. Several of these chemicals, however, have been shown to increase cerebrospinal fluid pressure in the brain, optic nerve, and spinal cord, and/or intraneuronal pressure in the perineurium surrounding the axons in the peripheral nervous system. This increased pressure has been correlated with decreased conduction capacity through the axon, ischemia to the neuronal tissue from decreased blood flow because of pressure against the blood vessels, and, if unrelieved, permanent axonal damage. Several of these chemicals havebeen shown to inhibit oxidative phosphorylation, while others uncouple oxidative phosphorylation. One chemical appears to inhibit an enzyme critical to cholesterol synthesis, thus destabilizing myelin. Another hypothesis for a mechanism of action may be in the ability of these compounds to alter membrane permeability.

Regional potassium distribution in the brain in forensic relevant types of intoxication preliminary morphometric evaluation using a histochemical method

A histochemical-morphometric method was used to measure potassium (K+) levels in gray and white matter of rats following sublethal intoxication with 11 different neurotoxic compounds of high forensic significance. Six rats were each given a single substance applied intraperitoneally, the same dosage being given to two animals each. The animals were subsequently killed, the brains immediately frozen, and cryosections cut. K+ levels were evaluated morphometrically. A drop in K+ levels was used as the criterion for cytotoxic edema. Application of ethanol, atropine, carbromal, carbon monoxide, morphine or triethyltin led to a rise in K+ levels in the gray matter and a simultaneous decline in the white matter. By contrast, administration of amitriptyline, glycerin, potassium cyanide, parathion or phenobarbital initiated an increase in K+ levels in both gray and white matter. A cytotoxic edema could thus be reliably excluded in these intoxications. Although the study design allows no statistical analysis, these conclusions are supported by the marked differences in K+ levels in gray and white matter induced by the different toxicants.

Increase in brain stem cytokine mRNA levels as an early response to chemical-induced myelin edema

This study examined the early response of pro-inflammatory and regulatory cytokines in the mouse brain following triethyltin (TET)-induced myelin injury characterized by edematous vacuolation. Following an acute intraperitoneal injection of triethyltin (TET) sulfate (3 mg/kg) to 17-day old CD1 mice, significant increases in brain stem TNF-alpha and IL-1alpha mRNA levels occurred at 6 and 24 h, respectively with elevations in TGF-beta1 and MIP-1alpha at 1 h. In the cortex, responses were limited to elevations at 6 h in TNF-alpha, TGF-beta1 and MIP-1alpha. These data suggest that a chemokine/cytokine response can occur with minimal alterations to the integrity of the myelin sheath and may contribute to the initial signaling mechanisms associated with demyelinating disorders.

In vivo characterization of cytotoxic intracellular edema by multicomponent analysis of transverse magnetization decay curves

RATIONALE AND OBJECTIVES

We investigated the multicompartmental nature of T2 decay in a specific white matter edema model.

METHODS

Triethyltin (TET) intoxication was produced in six male New Zealand White rabbits. Images were obtained over the 23-day study duration using a 64-echo Carr-Purcell-Meiboom-Gill (CPMG) sequence (repetition time = 3000 msec, echo time = 20 msec). T2 decay curves were extracted from 0.7 x 0.7 x 3.0 mm3 voxels in the corpus callosum and contiguous white matter tracts, cortex, thalamic nuclei, hypothalamic nuclei, and the masseter muscles. The curves were fit with biexponential functions.

RESULTS

Increased signal intensity in the corpus callosum was evident 2-3 days after the first TET injection. At this time, a substantial slowly relaxing component appeared in the decay curves of the corpus callosum and, to a lesser extent, in the thalamus and hypothalamus. Changes in the rabbits' body weight, general physical condition, and neurologic state paralleled the growth and regression of the second, slowly relaxing component.

CONCLUSION

The appearance and regression of a slowly decaying second component in the T2 decay curve is consistent with the formation and shrink-age of intracellular vesicles in the intramyelin sheaths of central white matter.

Threshold procedures for assessing the impact of agents on brain reward systems

Chemical effects on the reinforcing quality of electrical stimulation of the rat brain can be assessed using a variety of methods, most commonly by observing changes in response rates maintained under specific schedules of reinforcement. We present results demonstrating the utility of procedures for assessing the minimum amount of electrical stimulation required to support rat leverpress responding, that is, the brain-stimulation reward (BSR) threshold. In these threshold procedures, each leverpress produced by the rat decreases the duration of the electrical stimulus delivered to the posterior lateral hypothalamus until the rat fails to respond. The stimulus duration is then reset to its initial value and the procedure begins again. The last stimulus duration in a series supporting a response is defined as the stimulus duration (SD) threshold, and the mean SD threshold is determined daily. Stable SD thresholds are achieved within 2 weeks, and this measure is sensitive to agent-induced changes in rats' response to BSR. To illustrate the utility of this approach, data are presented showing that rats' BSR thresholds changed significantly following exposure to triethyltin or carbon monoxide. The results support the view that threshold methods can be used to dissociate agent-induced effects on brain reward systems and BSR quality from changes in performance or effects on other behavioral processes.

Triethyltin exposure suppresses synaptic transmission in area CA1 of the rat hippocampal slice

To examine the effects of TET on the electrophysiology of area CA1 of hippocampus, hippocampal slices were obtained from adult hooded rats and were maintained in vitro using standard techniques. Stimulating and recording electrodes were placed in the Schaffer collaterals and CA1 pyramidal cell body layer, respectively. Following baseline measurements, slices were exposed to either 0, 1, 3, 6, or 10 microM TET in the incubating medium. Both pyramidal cell excitability and recurrent/feedforward inhibition were suppressed in a dose-dependent manner within 3 hr postexposure. The evoked population spike and population excitatory postsynaptic potential (EPSP) were suppressed significantly by 2 hr postexposure for 1 and 3 microM TET exposures, and by 45 min postexposure for 6 and 10 microM exposures. A similar dose-dependency was observed for the suppression of recurrent/feedforward inhibition in hippocampal CA1. A second procedure tested the specificity of TET effects to axonal conduction of Schaffer collaterals. Both the stimulating and recording electrode were placed in the Schaffer collaterals so that both the Schaffer collateral population fiber volley and the CA1 pyramidal cell population EPSP could be recorded. TET exposure suppressed pyramidal cell EPSPs without significantly affecting the amplitude of Schaffer collateral fiber volleys. The results support the view that acute TET exposure suppresses synaptic transmission in area CA1 of hippocampus.

Acute poisoning with triethyltin in the rat. Changes in cerebral blood flow, cerebral oxygen consumption, arterial and cerebral venous blood gases

Experiments were conducted with rats in two groups. In group 1 (survival group) triethyltin was administered i.p. once in a dose of 2.5 mg/kg body weight and in group 2 (terminal group) the animals received triethyltin in a dose of 9 mg/kg of body weight. Twelve and twenty-four hours after triethyltin injection a decrease of 30 to 40% in cerebral blood flow was observed in both groups. A decrease of systemic arterial blood pressure and changes in hematocrit value were found at that time. Progressive bradycardia was noted in all animals at all times of observation. Additionally, 48 h after intoxication, cerebral blood flow was increased in both groups by 13 to 24% above control values. The described changes were accompanied by macroscopic features of brain edema and changes in the cerebral vascular network. Cerebral oxygen consumption was augmented by about 18% 12 h after triethyltin injection in group 1. After 24 h it decreased by about 60% compared with control values, and after 48 h it returned to normal. In group 2 cerebral oxygen consumption was decreased significantly throughout the observation period. This reflects the state of cerebral metabolism at these stages of cerebral edema. The results underscore the necessity of simultaneous monitoring of cerebral blood flow and blood gases in order to distinguish between the particular stages of brain edema revealed by biochemical tests.

The toxicity and neuropathology of dimethylethyltin and methyldiethyltin in rats

Triethyltin causes an increase in brain water with vacuolation of myelin sheaths, whereas trimethyltin is selectively damaging to neurons, especially of the hippocampal formations, causing chromatolysis, accumulation of cytoplasmic dense bodies and often cell death. The effects on rats of the analogues, dimethylethyltin and methyldiethyltin (oral LD50 14 mg/kg and 7.5-10.0 mg/kg respectively) are now reported. The dimethylethyl compound produces functional changes resembling those caused by trimethyltin, while the methyldiethyl compound causes responses similar to those produced by triethyltin. Structurally, however, the dimethylethyl compound, while producing marked nerve cell changes of the trimethyltin type also causes moderate vacuolation of myelin sheaths. By contrast, methyldiethyltin causes marked vacuolation of myelin sheaths of the triethyltin type and relatively minor neuronal changes of the trimethyltin type. These findings are discussed in terms of the structure-activity relationships of trialkyltin compounds.

Stimulation of astrocytes affects cytotoxic brain edema

Cytotoxic brain edema has been produced in rats by subacute intoxication with triethyltin (TET). Some animals were allowed to recover spontaneously, others were post-treated with an extract of Ginkgo biloba (EGB) for 1 to 4 weeks, beginning 3 days after intoxication was stopped. The time course of the resolution of the edema was studied biochemically and morphologically by light microscopy, histochemistry and electron microscopy (EM). Morphometric evaluation showed that the spontaneous reabsorption of TET-induced edema was very slow: it was evident only 2 weeks after ending TET administration and it required more than 4 weeks to be completed. EGB therapy markedly decreased the vacuolation, as well as the abnormal levels of water and sodium contents, 1 week after beginning the treatment. Less influence of EGB was observed at the later stages. During spontaneous recovery, astroglial cells in the edematous white matter of TET-intoxicated animals showed short and swollen processes containing few organelles, low levels of NADH- and NADPH-tetrazolium reductase activities and glial fibrillary acidic protein (GFAP)-immunofluorescence for about 2 weeks. During EGB therapy the astrocytes regained their cellular processes, containing intense oxidative enzyme activities and GFAP-immunofluorescence as early as after 1 week of treatment. In the EM, astrocytes often appeared hypertrophic, surrounding myelin vacuoles and displaying phagocytosis of myelin debris. We conclude that EGB can accelerate the reabsorption of TET-induced cerebral edema and improve the astroglial reaction.

Effect of an extract of Ginkgo biloba on triethyltin-induced cerebral edema

The effect of an extract of Ginkgo biloba was studied on cerebral edema in rats intoxicated with triethyltin chloride (TET). Brains of TET-treated rats showed elevated water and sodium levels and a significant increase in the sodium/potassium ratio. Animals treated with TET plus the extract did not show water and electrolyte changes. The course of intoxication and treatment was studied light- and electron-microscopically. A severe edema with extensive vacuolization was seen in the cerebral and cerebellar white matter. Morphometric measurements revealed a significant decrease in these manifestations of the cytotoxic edema when the animals were treated with an extract of Ginkgo biloba. Thus, we conclude that this extract has a protective effect on the development of a cytotoxic edema in the white matter of the brain.

Neuropathology of Rett syndrome

Autopsy studies in 8 girls with the Rett syndrome dying between 4 and 15 years showed: Diffuse cerebral atrophy/micrencephaly, with a decrease in brain weight by 13.8 to 33.8% of age-matched controls, apparently related to the duration of the disorder; Mild, but inconsistent diffuse cortical atrophy without developmental disorders apart from occasional microdysgenesis (three cases), but increased amounts of neuronal lipofuscin, and occasional mild astrocytic gliosis; Mild, but inconsistent spongy changes in cerebral and cerebellar white matter, optic nerve (two cases), and myelinated fascicles of the brainstem tegmentum, without signs of dys- or demyelination, and apparently different from the spongy myelinopathy common to aminoacidopathies; Most conspicuous was an underpigmentation of the substantia nigra which contained many fewer well-pigmented neurons for age (53-73%), and fewer pigmented granules per neuron, while the total number of nigral neurons and the triphasic substructure of neuromelanin were normal for age. No pathologic changes were seen in locus coeruleus, nucleus basalis of Meynert, and nucleus dorsalis raphe; Electron microscopy of autopsy material from an 11-year-old girl showed increased amounts of neuronal lipofuscin without signs of a storage disorder. Reactive and degenerating axons in the caudate nucleus were possibly related to the nigral changes, suggesting some dysfunction of the dopaminergic nigro-striatal system, while the synaptic organization of the neostriatum appeared unaffected. Peripheral nerve from a patient dying in advanced stage showed increased numbers of unmyelinated (regenerated?) axons, with almost no demyelination and few remyelinated axons, suggesting axonal degeneration rather than hypomyelination, but exogenous factors (malnutrition) cannot be excluded. The pathogenetic mechanisms of the morphologic brain lesions and their relations to clinical and neurochemical findings in Rett syndrome are unknown and deserve further intensive investigations.

Vascular permeability in acute triethyltin-induced brain edema studied with FITC-dextrans, sodium fluorescein and horseradish peroxidase as tracers

In golden hamsters, a study was made on the vascular permeability changes which might take place during the formation of triethyltin (TET)-induced brain edema. For this purpose, the animals received a single intravenous (i.v.) injection of TET sulphate (5-10 mg/kg b.wt) and groups of animals were studied 4 to 24 h thereafter. By the use of a new density gradient technique based on polyvinylcoated silica particles (1), it was shown that white matter edema was present already at 4 h after the TET injection. The edema then progressed during the following 20 h. Electron microscopy revealed that fluid accumulated in myelin vacuoles of the hamsters in the same way as has been described in other animal species. The macromolecular tracer, horseradish peroxidase mol.wt 40,000 injected i.v., did not leak out of the cerebral vessels during the period when edema developed. In order to find out if the formation of edema is associated with a vascular permeability increase to other and smaller markers, we used several fractions of FITC-dextrans varying from mol.wt 3,000 to 70,000 and determined their intracerebral localization with a histotechnical procedure. FITC-dextrans, mol.wt 70,000, did not leak out of the cerebral vessels in any of the TET intoxicated hamsters during the observation period of 24 h. The same was true for most animals given the other dextran fractions. However, FITC-dextrans, mol.wt 3,000-20,000 were present outside the vessels in the edematous optic nerves and corpus callosum in a few TET treated animals taken 16-24 h after the TET injection.(ABSTRACT TRUNCATED AT 250 WORDS)

Organometal-induced antinociception: a time- and dose-response comparison of triethyl and trimethyl lead and tin

Recent reports have demonstrated that organolead and -tin compounds can alter behavioral reactivity to noxious stimuli. To further define the dose response and temporal characteristics of these neurobehavioral effects, male Fischer 344 rats were injected sc with either one-fourth, one-half, or three-fourths the acute LD50 of triethyl lead (TEL), triethyl tin (TET), trimethyl lead (TML), trimethyl tin (TMT), or distilled water and tested on a 57.5 degrees C hot plate 1, 7, 14, 21, and 28 days after dosing. All four organometals altered hot plate latencies, but the magnitude and time course of these effects differed among the compounds. TEL produced a dose-related increase in latencies which was maximal 1 and 7 days postdosing and had dissipated by 28 days. In contrast, the group administered TML (3/4 LD50) exhibited a late developing antinocioception which became evident 14 days after dosing and persisted throughout the period of testing. The intermediate dose of TMT (1/2 LD50) also produced a delayed increase in response times which was observed 21 and 28 days post-treatment. The 3/4 LD50 dose of TMT produced increased hot plate latencies on all post-treatment test days except Day 14. TET (1/2 LD50) produced increased hot plate latencies 1, 7, 14, and 21 days postdosing and also induced a reversible ataxia and akinesia. Higher doses of TET proved lethal to 80% of the animals and lower doses failed to alter response times in the hot plate. These data demonstrate that trialkyl lead and tin compounds can produce time- and dose-related increases in hot plate latencies.

Effects of postnatal trimethyltin or triethyltin treatment on CNS catecholamine, GABA, and acetylcholine systems in the rat

The effects on brain neurochemistry of two neurotoxic tin compounds, trimethyltin (TMT) hydroxide and triethyltin (TET) sulfate, were examined. Long-Evans rats were treated with TMT hydroxide (1 mg/kg, i.p.) on alternate days from day 2 to 29 of life. These treatments caused a weight deficit of 10-20% by the time the animals were killed on day 55 by head-focused microwave irradiation. These TMT treatments are known to cause severe neuronal loss in the hippocampus and lesser damage in other brain regions. Accordingly, the concentration of gamma-aminobutyric acid (GABA) was decreased in the hippocampus; however, acetylcholine and choline concentrations were unaffected. These data suggest that TMT-induced effects on GABA systems are greater than that due simply to generalized neuronal loss. The TMT treatments also caused a significant decrease in dopamine concentrations in the striatum, but did not alter the concentrations of dihydroxyphenylacetic acid or homovanillic acid, the acidic metabolites of dopamine. Conversely, concentrations of dopamine and norepinephrine in the brain stem and norepinephrine in the cerebellum were not altered. Despite reports in the literature of TMT-induced neuronal damage in areas of the cortex, no effects on GABA, acetylcholine, or choline levels were found in the cortical areas examined, or in the hypothalamus. TET sulfate (0.3 mg/kg/day) was administered for 6 consecutive days of every week during days 2-29 of life. This dose is lower than that needed to cause intramyelin edema, yet it does result in long-term behavioral changes. Despite this, no changes in the concentration of any of the measured neurotransmitters or their metabolites were detected. In concert, these data demonstrate that neurochemical methods should not be used as neurological "screens," but rather to define specific mechanisms suggested by detailed behavior, pharmacological, and/or physiological studies.

Triethyltin decreases maximal electroshock seizure severity in adult rats

Acute and subacute treatment of adult rats with triethyltin bromide (TET) caused dose-dependent and time-dependent decreases in maximal electroshock seizure (MES) severity. This decrease in excitability was characterized by both a decrease in the percentage of animals exhibiting a maximal seizure and a corresponding decrease in the extension durations and an increase in the flexion durations. Acutely treated rats received (ip) 0, 1, or 5 mg/kg TET while subacutely exposed (po) received 0, 1, 5, or 10 ppm TET in the drinking water for 10 days. Experiments were designed so that the total consumed dose of TET, on a milligram per kilogram basis, equaled that in the acute experiment. No alterations in body weight were observed in either experiment. Acutely, the onset of action of TET was detectable within 0.5 hr. For the 1 mg/kg group, the effect peaked between 4 and 24 hr and completely recovered by 72 to 96 hr. For the 5 mg/kg group, the marked effect peaked at 4 hr, however, no recovery was observed. Subacute exposure for 1 to 2 days produced marked decreases in MES severity which were still present in the 5- and 10-ppm groups 14 days after cessation of exposure. Comparison of the onset and recovery data in the acute and subacute experiments revealed a close correspondence in similarly dosed rats. Comparison with other MES data from our laboratory revealed that adult rats were more sensitive to TET than adult mice or developing rats. Additionally, the MES test was able to detect subtle functional alterations in the central nervous system at lower doses of TET than previously reported neurobehavioral evaluation procedures.

Immediate and long-term alterations in maximal electroshock seizure responsiveness in rats neonatally exposed to triethyltin bromide

Neonatal rats were injected (sc) with 0, 0.25, 0.5, 1.0, 2.5, or 5.0 mg/kg triethyltin bromide (TET) in a 2% ethanol vehicle on Days 0, 5, 10, 15, and 20 postnatally. TET-exposed neonates exhibited a dose-dependent delay in the ontogenetic appearance of both the clonic and tonic maximal electroshock seizure (MES) responses which were apparent up to Day 45, as evaluated by the MES grade distributions and the durations of the individual phases of the MES. In marked contrast, adult rats (exposed to TET only as neonates) exhibited long-term increases in MES severity, as evaluated by the durations of the individual phases of the MES. At 75 days of age, a time when the 1.0 mg/kg developmentally TET-treated group exhibited an increased seizure severity, a single challenge dose of 1.0 mg/kg TET (ip) produced a proportional decrease in MES severity in both developmentally treated and control rats. No changes in preweaning or postweaning body weight were observed in the animals in the 0.25, 0.5, 1.0, or 2.5 mg/kg groups. A 30% decrease in weaning weight and an approximate 15% decrease in postweaning weight were observed in the 5.0 mg/kg group. These seizure results demonstrate that developmental exposure to TET produces immediate and long-term alterations in central nervous system functioning, which are of an opposite character. Interesting, we have previously shown that developmental lead exposure produces a similar developmental/adult dichotomy of effects with regard to the MES severity; however, the two patterns are reversed (D. A. Fox, S. R. Overmann, and D. E. Woolley (1979).

Triethyl tin-induced myelin oedema: an intermediate swelling state detected by X-ray diffraction

X-ray diffraction was used to probe the effects of triethyl tin (TET) on the periodicity and amount of membrane disorientation in the lamellar myelin from respiring optic and sciatic nerves in vitro as well as from nerves of rats treated in vivo through their drinking water. The diffraction patterns show that in vitro TET at concentrations of 4-100 microM affects C.N.S. but not P.N.S. myelin structure. A planar, concentric membrane array with a 200 A period is detected in the C.N.S.; this ordered, swollen myelin contrasts with the vacuolar and vesicular structure seen in thin-sections in TET-induced oedema. No effects of short-term in vivo treatment with TET are observed in either the C.N.S. or P.N.S. The finding that carbonic anhydrase (CA) inhibitors have no effect on the TET-induced structural changes indicates that the swelling we observe is not related to a CA-dependent process. In comparison, the TET effect is prevented by replacing the mobile ions with isotonic sucrose. We conclude that TET-induced swelling in C.N.S. myelin arises from an increase in ion transport followed by obligatory fluid movement. Further, the ordered, swollen structure we detect may be an intermediate state that exists transiently in vivo in TET intoxication and that precedes the gross swelling and vacuolization usually observed.

Effects of organotin compounds on maximal electroshock seizure (MES) responsiveness in mice. I. TRI(n-alkyl)tin compounds

Male mice (25-30 g) were injected (ip) with 0, 3.5 X 10(-6), or 17.5 X 10(-6) mol trimethyltin bromide (TMT), triethyltin bromide (TET), tri-n-propyltin chloride (TPT), or tri-n-butyltin bromide (TBT) per kg. Additional groups of mice were also injected (ip) with either 0 or 17.5 X 10(-6) mol sodium bromide (NaBr) or 17.5 X 10(-6) mol stannic bromide (SnBr4) per kg. The mice were tested with maximal electroshock seizure (MES) at 0.5, 4, 21-24, and 96 h following exposure to the organotin compounds. Mice exposed to TMT, TET, TPT, or TBT exhibited dose-dependent decreases in MES severity as evaluated by seizure-grade distributions and duration of tonic seizure phases. The tri-n-alkyltin compounds exhibited a structure-activity relationship in their ability to decreased maximal responsiveness to the MES test. In order of decreasing ability they were: TMT greater than TET greater than TPT greater than TBT. Administration of NaBr and SnBr4 did not alter MES responsiveness, indicating the essential role of the alkyl moieties of the tri-n-alkyltin compounds in producing alterations in central nervous system function.

Membrane lesions in cultured mouse neuroblastoma cells exposed to metal compounds

Tritiated 2-deoxy-D-glucose (dGlc) was rapidly taken up into cultured mouse neuroblastoma C1300 cells (clone 41A3). Upon perfusion the preloaded cultures slowly released radioactivity as [3H] 2-deoxy-D-glucose-6-phosphate ([3H]dGlc-6-P) (rate const. = 0.017 min-1) from a pool corresponding to 74% (t1/2 = 41 min) of the total radioactivity incorporated. Destruction of the plasma membrane of the cells by means of Triton X-100 (1.0%) resulted in a rapid and total release of the radioactivity. CH3HgCl, HgCl2, (C2H5)3SnCl and K2Cr2O7 all caused an increase in the passive cell membrane permeability to [3H]dGlc-6-P. A membrane toxic concentration (MTC) was defined as the concentration of the tested metal compound giving rise to an increase in the relative efflux from 1.0 to 1.2 during 60 min perfusion. Using this MTC-value, the membrane toxicity of the compounds could be ranked in the following order: CH3HgCl (MTC = 9 x 10(-7) M) greater than HgCl2 (MTC = 6 x 10(-6) M) greater than (C2H5)3SnCl (MTC = 3 x 10(-4) M) greater than K2Cr2O7 (MTC = 7 x 10(-4) M). Since this differential toxicity is in accordance with other reports it is concluded that 2-deoxy-D-glucose (dGlc) may be used together with 41A3 cells to screen metal compounds for their membrane toxicity.

Myelin oedema, optic neuropathy and retinopathy in experimental Stypandra imbricata toxicosis

Rats experimentally poisoned with the toxic plant Stypandra imbricata developed acute oedema of central and peripheral myelin and extensive axonal degeneration in the optic nerves. The oedema developed with vacuolation and splitting of myelin lamellae at the intraperiod line. Following recovery from acute intoxication, myelin oedema resolved after 6 to 12 weeks, but severe retinal degeneration and optic nerve atrophy remained. Morphological abnormalities in glial cells and axons were only found in the optic nerves. It was concluded that there is probably also a direct toxic effect on the axons of the optic nerve and the photoreceptor cells of the retina. The chemical nature of the toxin remains to be defined but the marked similarity of its toxic effects to those of hexachlorophene are noted.

Essential fatty acid deficiency and CNS myelin. Biochemical and morphological observations

Essential fatty acid (EFA) deficiency was induced by feeding pregnant rats a fat-free diet 10--12 days after impregnation and maintaining the offspring on this diet until 120 days of age. EFA-deficiency rats demonstrated marked alterations in the fatty acid composition of ethanolamine phosphoglycerides (EPG's) from myelin subfractions. A decrease in the fatty acids of the linoleic (n-6) and linolenic (n-3) families was accompanied by an increase in the non-essential fatty acids of the oleic (n-9) family. These alterations decreased the unsaturation index of heavy myelin by 23% and that of light myelin by 10%. The EPG fatty acid composition of heavy myelin from control animals contained a higher percentage of polyunsaturated fatty acids than the light myelin which contained more monounsaturated fatty acids. These differences may be a reflection of distinct anatomical locations or functional properties of the subfractions. The differences between light and heavy myelin EPG fatty acids were not maintained during EFA deficiency. Morphologically, 1 mum thick sections revealed vacuoles within the optic nerve of EFA-deficient rats. Ultrastructurally these vacuoles were identified as fibers undergoing Wallerian degeneration and fibers demonstrating intramyelinic splitting. No qualitative changes were found in oligodendrocytes, astrocytes or vascular elements within EFA-deficient optic nerve. EFA deficiency did not alter the diameter of fibers within the optic nerve. These results show that although there is no apparent decrease in the degree of myelination within the optic nerve, morphological changes do occur in fibers of EFA-deficient optic nerve concomitantly with alterations in the EPG fatty acids of myelin subfractions.

Triethyltin toxicity as a model for degenerative disorders

Triethyltin (TET) toxicity in mice was examined as a model for certain degenerative disorders. Spontaneous and elicited behavioral tests, electrophysiological measures and nervous system protein characterizations were used to study anomalies resulting from TET treatments. TET animals exhibited lowered spontaneous locomotor activity levels, increased sciatic nerve excitation threshold and conduction velocities, and increased power levels in the slower frequency components of their electroencephalograms. Performance in an active avoidance task suggest that the gross ultrastructural changes commonly seen in TET intoxication are not primarily responsible for the observed neurophysiological changes. Possible sites of action of TET, in both the peripheral and central nervous systems, that would produce these neurophysiological changes and the relationship of these changes to the behavioral symptoms are discussed.

Wernicke's encephalopathy: an experimental study in the rhesus monkey

Experimental Wernicke's encephalopathy, induced in rhesus monkeys with a diet lacking thiamine (vitamin B1), is characterized by cavitary necrosis of the striatum as well as a microvacuolar periventricular lesion of the brain stem such as occurs in man. With high resolution light microscopy and electron microscopy, the primary structural alteration in the brain stem lesion, and probably also in the striatum, appears to be that of widespread "blister" formation due to splitting of myelin at the intraperiod line. Microvascular alterations were minimal, even in the most severely affected regions. It is the myelin blisters which give rise to the spongy texture of the neuropil. A similar splitting of myelin has been described in several other experimental encephalopathies, and it is probable that it also occurs in Wernicke's encephalopathy in man.