Development and application of novel histochemical tracers for localizing brain connectivity and pathology.

FLUORO-GOLD: A NEW FLUORESCENT RETROGRADE AXONAL TRACER WITH NUMEROUS UNIQUE PROPERTIES: A new fluorescent dye, Fluoro-Gold, has been demonstrated to undergo retrograde axonal transport. Its properties include (1) intense fluorescence, (2) extensive filling of dendrites, (3) high resistance to fading, (4) no uptake by intact undamaged fibers of passage, (5) no diffusion from labeled cells, (6) consistent and pure commercial source, (7) wide latitude of survival times and (8) compatibility with all other tested neuro-histochemical techniques. © 1986. Fluoro-Jade C results in ultra high resolution and contrast labeling of degenerating neurons: The causes and effects of neuronal degeneration are of major interest to a wide variety of neuroscientists. Paralleling this growing interest is an increasing number of methods applicable to the detection of neuronal degeneration. The earliest methods employing aniline dyes were methodologically simple, but difficult to interpret due to a lack of staining specificity. In an attempt to circumvent this problem, numerous suppressed silver methods have been introduced. However, these methods are labor intensive, incompatible with most other histochemical procedures and notoriously capricious. In an attempt to develop a tracer with the methodological simplicity and reliability of conventional stains but with the specificity of an ideal suppressed silver preparation, the Fluoro-Jade dyes were developed. Fluoro-Jade C, like its predecessors, Fluoro-Jade and Fluoro-Jade B, was found to stain all degenerating neurons, regardless of specific insult or mechanism of cell death. Therefore, the patterns of neuronal degeneration seen following exposure to either the glutamate agonist, kainic acid, or the inhibitor of mitochondrial respiration, 3-NPA, were the same for all of the Fluoro-Jade dyes. However, there was a qualitative difference in the staining characteristics of the three fluorochromes. Specifically, Fluoro-Jade C exhibited the greatest signal to background ratio, as well as the highest resolution. This translates to a stain of maximal contrast and affinity for degenerating neurons. This makes it ideal for localizing not only degenerating nerve cell bodies, but also distal dendrites, axons and terminals. The dye is highly resistant to fading and is compatible with virtually all histological processing and staining protocols. Triple labeling was accomplished by staining degenerating neurons with Fluoro-Jade C, cell nuclei with DAPI and activated astrocytes with GFAP immunofluoresence. © 2005. ARTICLE ABSTRACT: The development of novel tracers and associated histochemical methods has always been need driven. One such need was the development of tracers that could be administered to discrete brain regions in vivo to subsequently reveal neuronal connectivity via axonal transport of the tracer. One such compound is Fluoro-Gold (F-G), which can be used to demonstrate retrograde axonal transport. Advantages of this fluorescent tracer include brightness, sensitivity, contrast, stability, permanence and compatibility with multiple labeling studies. It may be applied to resolve either the afferent or efferent connections of brain regions of interest. Another need addressed was for a simple and definitive way to localize degenerating neurons in brain tissue sections. This led to the development of Fluoro-Jade B (FJ-B) and Fluoro-Jade C (FJ-C). Advantages of these fluorescent histochemical tracers include high specificity, resolution, contrast, stability and suitability for use in multiple labeling studies. These methods can be applied to detect both apoptotic and necrotic neuronal degeneration following a variety of insults including physical trauma, neurodegenerative disease and a wide variety of neurotoxicants. This article is part of a Special Issue entitled SI:50th Anniversary Issue.

Neuroprotective effect of the chemical chaperone, trehalose in a chronic MPTP-induced Parkinson's disease mouse model.

Parkinson's disease (PD) is a progressive motor disease of unknown etiology in the majority of cases. The clinical features of PD emerge due to selective degeneration of dopamine (DA) neurons in the substantia nigra pars compacta (SNc), which project to the caudate putamen (CPu) where they release DA. In the current in vivo mouse model study, we tested trehalose for its ability to protect against 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-induced damage to DA neurons. Trehalose is a naturally occurring disaccharide present in plants and animals and appears capable of protecting cells against various environmental stresses. The effect of trehalose is likely due to its action as a pharmacological chaperone which promotes protein stability. In the present study, there were four treatment groups: saline only (control); probenecid only; MPTP+probenecid; and trehalose+MPTP+probenecid. MPTP-induced losses in tyrosine hydroxylase and DA transporter immunoreactivity in the ventral midbrain SNc and CPu were significantly reduced by trehalose. Decreases in CPu dopamine levels produced by MPTP were also blocked by trehalose. Microglial activation and astrocytic hypertrophy induced by MPTP were greatly reduced by trehalose, indicating protection against neuroinflammation. These effects are commensurate with the observed trehalose sparing of motor deficits produced by MPTP in this mouse model. Two tight junctional proteins, ZO-1 and occludin, are downregulated following MPTP treatment and trehalose blocks this effect. Likewise, the glucose transporter-1 that is expressed in brain endothelial cells is also protected by trehalose from MPTP-induced down-regulation. This study is the first to demonstrate using fluoro-turoquoise FT gel perfusion techniques, the protection afforded by trehalose from MPTP-induced damage to microvessels and endothelial and suggests that trehalose therapy may have the potential to slow or ameliorate PD pathology.

The use of recently developed histochemical markers for localizing neurotoxicant induced regional brain pathologies.

Neuronal and vascular brain components are interrelated morphologically, physiologically and developmentally. Due to this close interrelationship, it is often difficult to understand the cause and effect relationship between neuronal vs. vascular dysfunction and pathology. This review will discuss four of the more promising recent developments for detecting vascular pathology, and will compare them with the labeling pattern seen with markers of glial and neuronal pathology; following exposure to well characterized neurotoxicants. To detect the vascular dysfunction in the brain, we recently developed a Fluoro-Turquoise gelatin conjugate (FT-gel), a fluorescent probe that helps to delineate between healthy vs. sclerotic vessels. Similarly, we have investigated the potential for Fluoro-Gold to label in vivo all the endothelial cells in the brain as they co-localize with RECA, an endothelial cell marker. We have also developed Amylo-Glo, a fluorescent tracer that can detect neurotoxic A-beta aggregates in the brain. In this article, we will discuss the potential use of these novel histochemical markers to study the neurotoxicant induced brain. We will also discuss neurovascular strategies that may offer novel therapeutic opportunities for neurodegenerative disorders.

K114 inhibits A-beta aggregation and inflammation in vitro and in vivo in AD/Tg mice.

Alzheimer's disease (AD) is the most common age related human neurodegenerative disorder. The major histopathological characteristics of the AD brain are extracellular amyloid-beta (Aß) peptide loaded plaques and intraneuronal neurofibrillary tangles made of phosphorylated tau proteins. Amyloid plaques consist primarily of aggregated Aß1-42 and Aß1-40 peptides. The aim of our current study was to test novel ligands/agents with the potential to disrupt or inhibit the aggregation of Aß peptide, specifically K114, (trans,trans)-1-bromo-2,5-bis(4-hydroxystyryl)benzene, which was initially developed as a potential positron emission tomography (PET) ligand for the in vivo detection of amyloid plaques. Systemic administration of K114 has been shown in the AD/transgenic (Tg) mouse model to be capable of crossing the blood-brain barrier (BBB) and be colocalized with amyloid plaques. In this study we determined whether K114 has the potential to inhibit Aß aggregation in vitro in AD/Tg mice and also tested, in vivo, whether chronic daily orally administered K114 has any therapeutic potential as evidenced by inhibition or reduction of the deposits of amyloid aggregates in the brains of AD/Tg mice. Our results demonstrated that K114 strongly blocked, in vitro, the aggregation of Aß peptide in the amyloid plaques of AD/Tg mouse brain. Systemic treatment with K114 was also effective in significantly reducing the deposits of amyloid plaques in the brains of living transgenic AD mice. Additionally, K114 significantly inhibited the typically observed plaque associated astrocytic activation, as revealed by GFAP immunohistochemistry, suggesting possible anti-inflammatory properties.

Systemic administration of fluoro-gold for the histological assessment of vascular structure, integrity and damage.

Fluoro-Gold (F-G) has been used extensively as a fluorescent retrograde neuronal-track tracer in the past. We now report that intraperitoneal administration of 10 to 30 mg/ kg of F-G from 30 min to 7 days prior to sacrifice labels vascular endothelial cells of the brain, choroid plexus and meninges and can be used to assess vascular integrity and damage. F-G vascular labeling co-localized with rat endothelial cell antigen (RECA-1) in the membrane. F-G also intensely labeled the nuclei of the endothelial cells, and co-localized with propidium iodide staining of these nuclei. As well, the administration of F-G during neurotoxic insults produced by amphetamine, kainic acid or "penetrating" wound to the brain can detect where vascular leakage/ hemorrhage has occurred. Histological methods to detect F-G labeled brain vasculature were performed in the same manner as that used for fluorescent visualization of neuronal elements labeled with F-G after perfusion fixation and coronal sectioning (15 to 40 µm) of the brain. This in vivo F-G labeling of endothelial cells and their nuclei yields a clear picture of the integrity of the vasculature and can be used to detect changes in structure. Vascular leaks after "penetrating" wounds through the cortex and striatum, hyperthermic amphetamine exposure or excitotoxic kainate exposure were detected by F-G in the extracellular space and via parenchymal F-G subsequently labeling the terminals and neurons adjacent to the lesioned or damaged vasculature. Further studies are necessary to determine the extent of the leakage necessary to detect vasculature damage. Visualization of the F-G labeling of vasculature structure and leakage is compatible with standard fluorescent immuno-labeling methods used to detect the presence and distribution of a protein in histological sections. This method should be directly applicable to studying brain vascular damage that occurs in the progression of Alzheimer's disease, diabetes and for monitoring the brain vascular changes during development.

Neurovascular changes in acute, sub-acute and chronic mouse models of Parkinson's disease.

Although selective neurodegeneration of nigro-striatal dopaminergic neurons is widely accepted as a cause of Parkinson's disease (PD), the role of vascular components in the brain in PD pathology is not well understood. However, the neurodegeneration seen in PD is known to be associated with neuroinflammatory-like changes that can affect or be associated with brain vascular function. Thus, dysfunction of the capillary endothelial cell component of neurovascular units present in the brain may contribute to the damage to dopaminergic neurons that occurs in PD. An animal model of PD employing acute, sub-acute and chronic exposures of mice to methyl-phenyl-tetrahydropyridine (MPTP) was used to determine the extent to which brain vasculature may be damaged in PD. Fluoro-Turquoise gelatin labeling of microvessels and endothelial cells was used to determine the extent of vascular damage produced by MPTP. In addition, tyrosine hydroxylase (TH) and NeuN were employed to detect and quantify dopaminergic neuron damage in the striatum (CPu) and substantia nigra (SNc). Gliosis was evaluated through GFAP immunohistochemistry. MPTP treatment drastically reduced TH immunoreactive neurons in the SNc (20.68 ± 2.83 in acute; 22.98 ± 2.14 in sub-acute; 10.20 ± 2.24 in chronic vs 34.88 ± 2.91 in controls; p<0.001). Similarly, TH immunoreactive terminals were dramatically reduced in the CPu of MPTP treated mice. Additionally, all three MPTP exposures resulted in a decrease in the intensity, length, and number of vessels in both CPu and SNc. Degenerative vascular changes such as endothelial cell 'clusters' were also observed after MPTP suggesting that vasculature damage may be modifying the availability of nutrients and exposing blood cells and/or toxic substances to neurons and glia. In summary, vascular damage and degeneration could be an additional exacerbating factor in the progression of PD, and therapeutics that protect and insure vascular integrity may be novel treatments for PD.

Efficacy and toxicity of clioquinol treatment and A-beta42 inoculation in the APP/PSI mouse model of Alzheimer's disease.

Alzheimer's disease (AD), the most common human neurodegenerative disease, is characterized pathologically by numerous deposits of amyloid plaques in the brain. Systemic administration of clioquinol (CQ) and inoculation with amyloid-beta42 (Aß42) vaccines have been demonstrated to significantly inhibit deposits of amyloid in AD brains. However, each of these treatments has also been reported to be neurotoxic. The generation of transgenic mice models of AD has made it possible to study aspects of this disease employing experimental animals. In the present study, we investigated the efficacy and toxicity of CQ and Aß42 vaccine in a transgenic AD (APP/PS1) mouse model. Our results confirmed that both CQ and Aß42 vaccine were effective in significantly reducing the deposits of amyloid in the brains of transgenic AD mice. We also report here that systemic CQ induces myelinopathies in the dorsal lateral geniculate nucleus (DLG), which was almost devoid of amyloid plaques and is the primary site of retinal efferent projections via the optic nerve. This is the first report that systemic administration of CQ causes myelinopathies in the central nervous system (CNS) of a transgenic AD mouse model as well as wild-type mice. Inoculation with an Aß42 vaccine was also found, for the first time, to result in a significant increase in plaque-independent astrocytic hyperplasia in the dorsal part of the lateral septal nucleus (LSD) which was also devoid of plaques, reflecting potential brain inflammatory processes.

Longitudinal behavioral changes in the APP/PS1 transgenic Alzheimer's disease model.

The APP/PS1 double transgenic mouse is an Alzheimer's Disease-like model. However, cognitive deficits measured at one age do not necessarily indicate age-related progressions. Further, results of the most widely used behavioral assessment, water maze performance, are generally limited to 1-2 endpoints. Here, male APP/PS1 and noncarrier wildtypes (n=11/group) were assessed at 7-15 months of age for water maze, open field, and motor coordination performance. Body weights and motor coordination were comparable for both groups throughout. Beginning at approximately 9 months of age, the transgenic group exhibited hypoactivity in the open field which continued throughout. Latency to locate the platform and swim path length were longer in the transgenic group; however, these appeared to be more related to increased floating and thigmotactic behavior and only partially related to a cognitive impairment. Age-related decrements in performance were not substantial; however, substantial plaque numbers were measured in six representative 16-month-old transgenic mice. The stability of water maze performance may be related to the longitudinal testing and repetitive experience, which previous research has demonstrated can confer beneficial effects on behavior and plaque deposition in transgenic Alzheimer's Disease models [1]. These results emphasize the importance of measuring multiple water maze endpoints and demonstrate the feasibility of longitudinal assessments in this model.

Characterization of myelin pathology in the hippocampal complex of a transgenic mouse model of Alzheimer's disease.

We have characterized the myelin changes observed within the hippocampal complex (HC) of a transgenic (Tg) mouse model of Alzheimer's disease (AD). Individual myelinated fibers were labeled with Black-Gold II while amyloid plaques were labeled with either Congo Red or Pan-A-beta immunofluoresence. Myelinated fibers were never seen passing through amyloid plaques in any region, while conspicuous myelin pathology was seen within, and immediately adjacent to, the amyloid plaques in the HC of the AD-Tg mouse. This pathology consisted of a complete disruption of myelinated fibers passing through the plaque and the region immediately adjacent to the plaques exhibited an edematous swelling of the fibers. This pathology was most frequently observed within the molecular and polymorph layers of the dentate gyrus and the molecular layer of Ammon's horn. The remaining layers of Ammon's horn exhibited minimal myelin pathology, while moderate myelinopathy was observed in the subiculum. Since the HC is integral for memory function, these findings may help account for the memory problems so characteristic of the disease process. Because the molecular layers of the dentate gyrus and Ammon's horn are the sites of inputs to the HC, the extensive myelin pathology observed in these regions would imply functional deafferentation of the HC. The appearance of some Black-Gold II positive debris within the plaques may reflect a possible cascade mechanism whereby the presence of plaques results in myelin degeneration, some of which is incorporated within the plaque, causing it to further expand in a self-perpetuating fashion.

One-step labeling of degenerative neurons in unfixed brain tissue samples using Fluoro-Jade C.

Neurodegeneration is the underlying cause of a vast majority of neurological disorders and often a result of brain trauma, stroke, or neurotoxic insult. Here we describe a simple method for labeling degenerating neurons in unfixed brain tissue samples. This method could provide a new avenue for identifying and harvesting degenerative neurons from unfixed brain tissues for subsequent molecular analyses.

Brain region-specific neurodegenerative profiles showing the relative importance of amphetamine dose, hyperthermia, seizures, and the blood-brain barrier.

Understanding the neurotoxic effects of acute high-dose exposures of laboratory animals to methamphetamine (METH) and amphetamine (AMPH) is of relevance to understanding the neurotoxicity incurred in humans from overdose or abuse of these substances. We present recent findings on the neurodegenerative effects of both a single high dose of 40 mg/kg and a 4-dose exposure to AMPH in the rat. Comparing these results with those we have previously observed in rodents exposed to either AMPH or METH helps further address how dose, hyperthermia, seizures and blood-brain barrier (BBB) disruption interact to produce neurodegeneration. With regard to the 4-dose paradigm of AMPH exposure in the rat, our recent data, combined with previous findings, clearly show the importance of dose and hyperthermic interactions in producing neurodegeneration. The single high AMPH dose invariably resulted in extreme hyperthermia and brief episodes of clonic-tonic seizure activity in many rats. However, motor behavior indicative of status epilepticus was not observed in rats receiving the 40 mg/kg AMPH, which contrasts with what we have previously seen with 40 mg/kg METH dose in the mouse. This may explain why, unlike the mice given METH, there was minimal BBB disruption in the amygdala of rats. Nonetheless, in some of the surviving rats there was extensive neurodegeneration in the hippocampus and intralaminar and ventromedial/lateral thalamic nuclei. Early BBB disruption was seen in the hippocampus and may play an important role in the subsequent neurodegeneration. The fact that status epilepticus does not occur in rats that have major hippocampal and thalamic degeneration indicates that such damage may also occur in humans exposed to high doses of AMPH or METH in the absence of status epilepticus or prominent motor manifestations of seizure activity.

Neurotoxic-related changes in tyrosine hydroxylase, microglia, myelin, and the blood-brain barrier in the caudate-putamen from acute methamphetamine exposure.

Changes in the histological morphology of the caudate-putamen (CPu) were determined after a high-dose methamphetamine (METH) exposure in an effort to elucidate whether BBB disruption plays a role in CPu neurotoxicity. This was accomplished by evaluating the tyrosine hydroxylase immunoreactivity (TH-IR), isolectin B4 reactivity, Black Gold II (BG-II) and Fluoro-Jade C (FJ-C) staining, and immunoreactivity to mouse immunoglobulin G (IgG-IR) in adult male mice at 90-min, 4-h, 12-h, 1-day, and 3-day post-METH exposure. The IgG-IR indicated that the BBB was only modestly altered in the CPu at time points after neurodegeneration occurred and dependent on hyperthermia and status epilepticus. The modest CPu IgG-IR changes observed in the perivascular areas indicated that immunoglobulins were present on some CPu microglia 1 day or more after METH. The first signs of CPu damage were swellings in the TH-IR axons, myelin damage, and a few degenerating neurons at 4-h post-METH. The loss of TH-IR was dependent on hyperthermia but not seizures or CPu neurodegeneration, and the TH-IR was virtually absent throughout the CPu within 12 h. Surprisingly, signs of FJ-C labeling (degenerating) axons in the CPu were seen only in the regions of pronounced somatic neurodegeneration and independent of TH-IR loss. Microglial activation did not occur until 1 day or more post-METH. In summary, a major BBB disruption within the CPu does not directly contribute to neurotoxicity in this single high-dose METH exposure. However, seizure activity produced or exacerbated by amygdalar BBB disruption can significantly increase CPu somatic neurodegeneration (but not affect dopamine (DA) terminal damage). The time course of microglial activation indicates a response to the neurodegeneration, myelin damage, and/or damaged DA terminals after loss of TH-IR.

Fluoro-Ruby labeling prior to an amphetamine neurotoxic insult shows a definitive massive loss of dopaminergic terminals and axons in the caudate-putamen.

Fluoro-Ruby (FR) was injected into the substantia nigra (SNc) to label dopaminergic axons and terminals in the caudate putamen (CPu) of rats 7 days prior to a neurotoxic d-amphetamine (AMPH) exposure. Three days after AMPH exposure, a massive loss in the TH immunoreactive (TH(+)) axons and terminals was seen in the CPu. The FR-labeled (FR(+)) axons and terminals in the CPu were greatly diminished with those remaining being enlarged or swollen after AMPH. Fluoro-Jade C (FJ-C) labeling was used to verify AMPH-induced axonal and terminal degeneration. This study demonstrates that fluorescent anterograde tract tracers can be used to show the subsequent axonal and terminal degeneration after systemic exposures to toxins and provides direct evidence that CPu axons and terminals from SNc dopaminergic neurons can be destroyed after neurotoxic exposure to AMPH.

Neurohistochemical biomarkers of the marine neurotoxicant, domoic acid.

Domoic acid and its potent excitotoxic analogues glutamic acid and kainic acid, are synthesized by marine algae such as seaweed and phytoplankton. During an algal bloom, domoic acid may enter the food web through its consumption by a variety of marine organisms held in high regard as seafoods by both animals and humans. These seafoods include clams, mussels, oysters, anchovies, sardines, crabs, and scallops, among others. Animals, such as pelicans, cormorants, loons, grebes, sea otters, dolphins, and sea lions, which consume seafood contaminated with domoic acid, suffer disorientation and often death. Humans consuming contaminated seafood may suffer seizures, amnesia and also sometimes death. In addition to analytical measurement of domoic acid exposure levels in algae and/or seafood, it is useful to be able to identify the mode of toxicity through post-mortem evaluation of the intoxicated animal. In the present study, using the rat as an animal model of domoic acid intoxication, we compared histochemical staining of the limbic system and especially the hippocampus with degeneration-selective techniques (Fluoro-Jade and silver), a conventional Nissl stain for cytoplasm (Cresyl violet), a myelin-selective stain (Black-Gold), an astrocyte-specific stain (glial fibrillary acidic protein), early/immediate gene responses (c-Fos and c-Jun), as well as for heat shock protein (HSP-72) and blood-brain barrier integrity (rat IgG). The results demonstrate that the degeneration-selective stains are the biomarkers of domoic acid neurotoxicity that are the most useful and easy to discern when screening brain sections at low magnification. We also observed that an impairment of blood-brain barrier integrity within the piriform cortex accompanied the onset of domoic acid neurotoxicity.

Fluoro-Jade C results in ultra high resolution and contrast labeling of degenerating neurons.

The causes and effects of neuronal degeneration are of major interest to a wide variety of neuroscientists. Paralleling this growing interest is an increasing number of methods applicable to the detection of neuronal degeneration. The earliest methods employing aniline dyes were methodologically simple, but difficult to interpret due to a lack of staining specificity. In an attempt to circumvent this problem, numerous suppressed silver methods have been introduced. However, these methods are labor intensive, incompatible with most other histochemical procedures and notoriously capricious. In an attempt to develop a tracer with the methodological simplicity and reliability of conventional stains but with the specificity of an ideal suppressed silver preparation, the Fluoro-Jade dyes were developed. Fluoro-Jade C, like its predecessors, Fluoro-Jade and Fluoro-Jade B, was found to stain all degenerating neurons, regardless of specific insult or mechanism of cell death. Therefore, the patterns of neuronal degeneration seen following exposure to either the glutamate agonist, kainic acid, or the inhibitor of mitochondrial respiration, 3-NPA, were the same for all of the Fluoro-Jade dyes. However, there was a qualitative difference in the staining characteristics of the three fluorochromes. Specifically, Fluoro-Jade C exhibited the greatest signal to background ratio, as well as the highest resolution. This translates to a stain of maximal contrast and affinity for degenerating neurons. This makes it ideal for localizing not only degenerating nerve cell bodies, but also distal dendrites, axons and terminals. The dye is highly resistant to fading and is compatible with virtually all histological processing and staining protocols. Triple labeling was accomplished by staining degenerating neurons with Fluoro-Jade C, cell nuclei with DAPI and activated astrocytes with GFAP immunofluoresence.

Demonstration and localization of neuronal degeneration in the rat forebrain following a single exposure to MDMA.

Methylenedioxymethamphetamine (MDMA, Ecstasy) is a powerful releaser of serotonin. Increasing recreational use of this stimulant and hallucinogenic drug has raised concerns about its potential to produce brain damage. The vast majority of previous research studies have focused on the compound's ability to deplete serotonin (5-hydroxytryptamine, 5-HT) from axon terminals. Despite extensive research on this '5-HT terminal neurotoxicity', a much less studied aspect of MDMA toxicity involves its ability to actually kill nerve cells. Only two prior studies mention the existence of MDMA-induced neuronal degeneration, as reflected by a limited number of argyrophylic neurons within the somatosensory cortex, following very high doses of MDMA. The development of Fluoro-Jade B as a simple and reliable marker of neuronal degeneration has allowed us to conduct the first comprehensive localization of MDMA induced neuronal degeneration throughout the entire rat forebrain. In addition to the previously reported neuronal degeneration within parietal cortex, degenerating neurons were also observed in the insular/perirhinal cortex, the ventromedial/ventrolateral thalamus, and the tenia tecta. The extent of neuronal degeneration observed generally correlated with the degree of hyperthermia achieved.

The progression of neuronal, myelin, astrocytic, and immunological changes in the rat brain following exposure to aurothioglucose.

Aurothioglucose (ATG) is presently employed both by clinicians in the treatment of advanced rheumatoid arthritis and by neuroscience researchers to generate lesions around the circumventricular organs (CVOs) of rodent brains, resulting in obese animals. Although the existence of such lesions is well documented, there is relatively little information concerning the changes over time of the different cell types in the regions surrounding the CVOs. To address this question, specific markers allowing identification of four distinct cellular populations were used to characterize respective changes over time. Generally, regions adjacent to the CVOs were more vulnerable than the CVOs themselves, while more caudal structures were more frequently lesioned than more anterior CVO regions. Vascular and glial cells appeared to be the initial targets of ATG, while neuronal cell death occurred subsequent to the inflammatory response. The results of this study help resolve the mechanism of ATG toxicity as reflected by a cascade of pathologies that is consistent with disparate cell types exhibiting specific changes at specific times.

Relations between brain pathology and temporal lobe epilepsy.

Temporal lobe epilepsy, the most common type of epilepsy in adult humans, is characterized clinically by the progressive development of spontaneous recurrent seizures of temporal lobe origin and pathologically by hippocampal neuronal loss and mossy fiber sprouting. In this study, we sought to test the prominent hypothesis that neuronal loss and mossy fiber sprouting play a critical role in the genesis and progression of temporal lobe epilepsy. Rats receiving a single kainic acid injection experienced a single sustained episode of epileptic status with massive neuronal loss and mossy fiber sprouting, whereas rats receiving triple kainic acid injections experienced two priming episodes and one sustained episode of epileptic status with no detectable neuronal loss and mossy fiber sprouting. Early in the process of chronic seizure development, primed rats that failed to show detectable neuronal loss and mossy fiber sprouting exhibited a starting date and a frequency of spontaneous recurrent seizures similar to those of nonprimed rats that showed massive neuronal loss and mossy fiber sprouting. However, nonprimed rats displayed significantly prolonged episodes of spontaneous recurrent seizures over the whole process of chronic seizure development and more frequent severe seizures later in the process. Similar results were observed in both Fischer-344 and Wistar rats as well as in the rat pilocarpine preparation of temporal lobe epilepsy. These results fail to reveal a relation between neuronal loss-mossy fiber sprouting and the genesis of temporal lobe epilepsy but suggest that neuronal loss, mossy fiber sprouting, or both contribute to the intensification of chronic seizures.