Resveratrol protects neurons from cannulae implantation injury: implications for deep brain stimulation

Brain-implantable electrodes such as those used in deep brain stimulation (DBS) have a promising future in end-stage Parkinson's disease therapy. However, there is considerable injury when electrodes penetrate brain tissue. For instance, broken blood vessels and glial scar formation may impede continual DBS or electrical recording from specific neurons. To begin addressing this key safety issue, we tested the therapeutic potential of resveratrol in reducing brain trauma caused by DBS-like surgery. Microinfusion of resveratrol (10 μM) directly applied to the sub-thalamic nucleus (STN) of the rat brain significantly minimized the formation of astrocytic gliosis in response to a 27-G precision-glide cannula implant. The therapeutic effects of resveratrol extended to the "kill zone", a boundary zone of about 100 μm comprising the cannula implant and surrounding neurons. We also found that resveratrol not only provided almost complete protection from mechanical injury to the brain, but that it also prevented undesirable motor deficits often seen in animals with lesions to the STN. Lastly, continuous infusion of resveratrol over a 4-week period led to the inhibition of pro-apoptotic, neurodegenerative and cell division cycle genes that may be associated with a reduction in astrocytic gliosis and glial scar formation within the STN. Taken together, these data suggest that application of resveratrol to the brain is an effective adjunct surgical procedure for minimizing acute neuronal injury when electrodes are implanted directly into the STN.

Undergraduate Neuroscience Education in the U.S.: An Analysis using Data from the National Center for Education Statistics

Despite an apparent increase in undergraduate neuroscience programs offered by colleges and universities, there has been little effort to document this growth. In the present report we describe our analysis of the expansion of undergraduate neuroscience programs of study over more than 20 years and detail a number of institutional characteristics of colleges and universities that offer undergraduate neuroscience programs. These data reveal more than 100 institutions with undergraduate neuroscience programs as well as over 2000 college graduates that majored in neuroscience in 2008-2009. Understanding the current number as well as growth trends of undergraduate neuroscience programs found in U.S. colleges and universities has implications for neuroscience educators as well as for the funding of neuroscience research and educational activities.

Magnetic resonance imaging and spectroscopy in a mouse model of schizophrenia

Metabolic brain abnormalities, as demonstrated by (1)H-magnetic resonance spectroscopy, are common occurrences in adult schizophrenia. As mice share important biochemical and genomic similarities with humans, we tested whether brain metabolic abnormalities also occur in a transgenic mouse model of schizophrenia. In vivo(1)H-magnetic resonance spectroscopy at 4.7T of the chakragati mouse brain revealed abnormalities in relative levels of choline and N-acetylaspartate compounds. These results are consistent with a prior proposal that deficits in metabolite ratios may be common features of psychotic disorders. Thus, chakragati mice recapitulate certain aspects of the human disease phenotype and further support the utility of this animal model for understanding causal factors underlying uniquely human brain diseases.

Endothelial heat shock response in cerebral ischemia

Blood vessels and nerve fibers often course alongside one another in an orderly fashion throughout the brain. This clustering gives rise to a reciprocal signaling network between endothelial and nerve cells that follows highly stereotyped anatomical patterns. One such molecular signal that is produced by endothelial cells and acts on surrounding neurons is heat shock protein 70. Here we briefly review recent studies that have revealed a critical role of this signaling pathway during harmful insults to the brain, particularly during episodes of cerebral ischemia.

Expression profile of Bag 1 in the postmortem brain

Bag 1 is a protein intimately involved in signaling pathways that regulate cell survival. Here we examined the expression profile of Bag 1 in the brain to consider issues associated with the sampling of anti-apoptotic proteins in a rat model of the human postmortem process. Following a 4h postmortem interval, we analyzed the hippocampus of rats maintained at 24 or 4 degrees C storage temperatures using immunocytochemical and Western blotting techniques. Remarkably, postmortem tissue (up to 4h) showed a significant and prominent up-regulation of Bag 1 in CA1 and CA3 subfields of the hippocampal formation. Over-expression of Bag 1, however, could only be traced down to a storage temperature of 24 degrees C. These data suggest that storage temperatures, but not postmortem intervals, significantly affect the expression profile and cellular stability of Bag 1 proteins.

Blood content modulates the induction of heat shock proteins in the neurovascular network

Heat shock proteins are ubiquitous members of a family of molecular chaperones that protect various cell populations from injury. Up-regulation of heat shock proteins, particularly the 70 kDa species, bind selectively to denatured or partially damaged polypeptides that would otherwise perturb cell function and initiate cell death programs. In this regard, induction of heat shock proteins provides protection from cerebral ischemia in animal models of stroke. Endothelial cells, in particular, are intimately involved in the above protective event as these cells mount a stress response with induction of the 70 kDa heat shock protein. However, the coupling of heat shock proteins and the neurovascular response are not yet known. Here we show that blood content is an important factor in this stress response as rats devoid of blood content do not display a heat shock response in the microvasculature of the hippocampal formation. This lack of stress response, however, is reversed when rats are reperfused with exogenous rat or human blood content. We propose a new ischemic-sensing role for blood that serves to integrate information about protein-damaging conditions and heat shock protein levels in the neurovascular network. Further characterization of this sensing role could represent an attractive new approach to treatment of global ischemia and other microvascular pathologies.

Distribution of constitutively expressed MEF-2A in adult rat and human nervous systems

Myocyte enhancer factor 2A (MEF-2A) is a calcium-regulated transcription factor that promotes cell survival during nervous system development. To define and further characterize the distribution pattern of MEF-2A in the adult mammalian brain, we used a specific polyclonal antiserum against human MEF-2A to identify nuclear-localized MEF-2A protein in hippocampal and frontal cortical regions. Western blot and immunocytochemical analyses showed that MEF-2A was expressed not only in laminar structures but also in blood vessels of rat and human brains. MEF-2A was colocalized with doublecortin (DCX), a microtubule-associated protein expressed by migrating neuroblasts, in CA1 and CA2 boundaries of the hippocampus. MEF-2A was expressed heterogeneously in additional structures of the rat brain, including the striatum, thalamus, and cerebellum. Furthermore, we found a strong nuclear and diffuse MEF-2A labeling pattern in spinal cord cells of rat and human material. Finally, the neurovasculature of adult rats and humans not only showed a strong expression of MEF-2A but also labeled positive for hyperpolarization-activated, cyclic nucleotide-regulated (HCN) channels. This study further characterizes the distribution pattern of MEF-2A in the mammalian nervous system, demonstrates that MEF-2A colocalizes with DCX in selected neurons, and finds MEF-2A and HCN1 proteins in the neurovasculature network.

Preliminary evidence for reduced social interactions in Chakragati mutants modeling certain symptoms of schizophrenia

Rodent models of schizophrenia provide powerful experimental tools for elucidating certain manifestations of the brain disease. The chakragati (ckr) mouse mutant, for instance, reproduces aberrant neuroanatomical and behavioral phenotypes observed in the corresponding human condition. To further investigate the utility of this mouse in the context of social behavior, we compared spontaneous behavioral activity and social interactions recorded during the subjective night among wild-type, heterozygous, and homozygous ckr mice. We found that both heterozygous and homozygous ckr animals failed to show appropriate norms of social behavior, including proximity, approach, huddling, and anogenital investigation in response to novel conspecifics. We further found that the anatomical distribution, topography, and connectivity of the neuropeptides oxytocin and vasopressin in the anterior hypothalamus did not differ among wild-type, heterozygous, or homozygous ckr animals. These latter findings suggest that although oxytocin and vasopressin influence social behavior, connectivity of such cells may not be phenotypically relevant for the observed social deficits seen in heterozygous and homozygous ckr mice. Collectively, ckr mice and their heterozygote kin are valuable experimental tools for pre-clinical studies involving disruptions of social behavior (e.g., social withdrawal).

Ventricular size mapping in a transgenic model of schizophrenia

Genetically engineered mice have been generated to model a variety of neurological disorders. The chakragati (ckr) mouse is beginning to provide valuable insights into the structural brain changes underlying certain manifestations of schizophrenia. For instance, these mice show enlargement of the lateral ventricles, an abnormality frequently reported as a structural aberration in the schizophrenic brain. As neither the anatomical pattern nor the timing of this ventricular enlargement is known, we used magnetic resonance imaging (MRI) techniques to non-invasively visualize the development of the ventricular system in 5-, 10- and 30-day-old ckr pups. High-resolution MR images obtained from these mutants showed a progressive enlargement of the lateral ventricles, starting at day 5 of postnatal life. These emerging deficits were associated with abnormalities in mid-saggital corpus callosum area and thickness, particularly in 30-day-old adolescent animals. At this time of development, aberrant behaviors that mimic certain symptoms of schizophrenia also appeared in ckr mice suggesting that structural changes in ventricular size predates the onset of psychotic-like behaviors. These results are viewed as further indication that pre- and peri-natal disturbances of the ventricular system and adjacent neural regions may be important pathogenic factors in schizophrenia. Application of MRI to the ckr mouse is relatively new but has great potential for clarifying the relationship between brain structure changes and genetically induced vulnerabilities to psychoses.

A neurobehavioral screening of the ckr mouse mutant: implications for an animal model of schizophrenia

A model of schizophrenia, the chakragati (ckr) mouse was serendipitously created as a result of a transgenic insertional mutation. The apparent loss-of-function of an endogenous gene produced mice that, when homozygous, displayed an abnormal circling behavior phenotype. To determine whether this phenotype could be corrected by atypical antipsychotics, we compared the effects of clozapine and olanzapine on rotational turns and hyperactivity. Both of these drugs successfully ameliorated circling behavior and hyperactivity in homozygous mice. The increased motor activity of these mutant mice was both qualitatively and quantitatively similar to that observed in wild-type animals treated with dizocilpine, an N-methyl-D-aspartate receptor antagonist that produces behaviors resembling positive symptoms of schizophrenia. Mice either homozygous or heterozygous for the mutation also displayed enlargement of the lateral ventricles, which was accompanied only in the homozygous genotype by a loss of individual myelinated axons in the striatum and agenesis of the corpus callosum. These structural brain deficits were selective in that the nigro-striatal dopamine system was normal in these homozygous mice. In addition, two types of interneurons in the neostriatum, namely those producing acetylcholine or nitric-oxide synthase were also devoid of significant structural abnormalities. These results indicate that the ckr mouse mutant could be used as a possible animal model to study the pathophysiology of schizophrenia and suggest possible strategies for treating the behavioral aspects of this brain disease.

BAX protein-immunoreactivity in midbrain neurons of Parkinson's disease patients

Apoptosis has been implicated in the pathophysiology of Parkinson's disease (PD). Components of signaling pathways that initiate cell death are highly concentrated in vulnerable substantia nigra (SN) neurons and may therefore contribute to the relentless demise of dopamine cells. Here, we report the distribution and organizational pattern of the pro-apoptotic protein BAX in the parkinsonian brain. Coronal sections (60 microm) of SN material from control and PD patients showed identical expression of BAX-immunoreactivity (IR) in all cases examined. Neurons positive for BAX-IR exhibited a discrete cytoplasmic and dendritic labeling that was conspicuously interspersed with previously unrecognized axonal spheroid-like inclusions. Direct comparisons revealed a difference in the aggregation of BAX-rich inclusions, with the parkinsonian brain containing more SN inclusions than control cases. BAX expression by midbrain neurons was confirmed by immunoblot analysis on SN extracts showing a specific band of approximately 21kDa, which is consistent with the known molecular weight of native BAX. These results suggest that apoptosis or programmed cell death may play an indirect role in idiopathic PD.

Characterization of fluoxetine plus olanzapine treatment in rats: a behavior, endocrine, and immediate-early gene expression analysis

A large number of individuals afflicted with psychiatric disorders, particularly depression with psychotic features, do not respond to conventional drug therapy. An option for this phenomenon is to augment a standard selective serotonin (5-HT) reuptake inhibitor with an atypical antipsychotic agent. In this regard, fluoxetine and olanzapine have been used concomitantly for treatment-resistant depression and bipolar depression. Although highly efficacious in terms of producing superior improvement of symptoms across a variety of psychological measures, the motor patterns, endocrine profiles, and intracellular signaling pathways affected by drug augmentation have not been determined. Here we show that fluoxetine (10 mg/kg) plus olanzapine (5 mg/kg) given to rats for 7 consecutive days (i.e., subchronic treatment) alters motor activity and diminishes spontaneous behaviors as measured by spatial position and angular path analyses. In addition, the same drug combination pattern sensitizes peak adrenal corticosterone secretion without altering serum glucose levels. We also show that subchronic fluoxetine and olanzapine exposure suppresses the induction of two immediate-early gene transcription factors (e.g., pCREB and FOS) that are associated with long-lasting changes in synaptic efficacy and structural modifications in the prefrontal cortex, piriform cortex, and hippocampus. These results suggest that fluoxetine plus olanzapine can interact in a fashion not predicted by the currently accepted model of fluoxetine monotherapy and provide insight into the synergistic actions of drug augmentation in patients with treatment-resistant depression.

Regulation of hippocampal parkin protein by corticosteroids

Parkin is a protein that when mutated leads to an inherited form of Parkinson's disease. Under normal conditions, this molecule has multiple functions in different cell types, including protein degradation and tumor suppression. To understand the relationship between parkin and circulating corticosteroid hormones, we studied the long-term depletion of corticosterone due to bilateral adrenalectomy in rats. We show that adrenalectomy deletes the expected expression of nuclear parkin in hippocampal neurons. Notably, the effect of adrenalectomy on parkin was prevented by corticosterone hormone replacement therapy. This finding suggests that adrenal hormones may be critical in sustaining parkin ubiquitinating activity in the rat hippocampus.

Rat strain differences to fluoxetine in striatal Fos-like proteins

Humans afflicted with mood disorders respond differently to antidepressant drug therapy. Different responses to psychoactive drugs are also observed in rats, and specific strains exhibit substantial differences in gene expression following synaptic activity. We examined the effects of fluoxetine on the induction of Fos-like proteins in Long-Evans and Sprague-Dawley rat brains. Fluoxetine elicited a strong induction of Fos in the striatum of Long-Evans but not Sprague-Dawley rats following acute drug exposure. This effect was specific to fluoxetine as two highly selective serotonin reuptake inhibitors, HD-31 and HD-50, as well as treatment with fenfluramine failed to replicate the observed differences in Fos. These differences in Fos expression between rat strains may represent variability in post-receptor pathways that ultimately mediate the therapeutic actions of fluoxetine.

Current trends in the pharmacologic and surgical treatment of Parkinson's disease

Recently, there has been a surge in the research regarding the pharmacologic and surgical treatment of Parkinson's disease. This article reviews the latest modes of medical and surgical therapy for Parkinson's disease. The latest drug therapy has consisted of levodopa, a combination of levodopa and carbidopa (Sinemet/Sinemet CR), and monoamine oxidase type B (MAO-B) inhibitors (selegiline hydrochloride). The surgical treatment modalities have been stereotaxic implantations of dopamine-producing tissues (such as adrenal medulla and fetal mesencephalon) into the caudate nucleus and ventral pallidotomy of patients with Parkinson's disease. The most recent work has been in the field of gene therapy. The implantation of cells genetically modified to express trophic factors and tyrosine hydroxylase for the synthesis of L-dopa from tyrosine has been proposed as a possible route for the treatment of Parkinson's disease. Although the etiology of the disease is still unknown, two recent theories are discussed.

Study of sympathetic innervation of cranial bones by axonal transport of horseradish peroxidase in the rat: preliminary findings

This study performed by intraneuronal tracing directly demonstrates the presence of sympathetic postganglionic fibers in the cranial vault of the rat. Superior cervical sympathetic ganglia were injected with horseradish peroxidase (HRP), and after a 48-hour period, to permit anterograde axonal transport, the animals were sacrificed after in situ perfusion. An area of the calvaria that included portions of the frontal and parietal bones was fixed, decalcified and sectioned. HRP-containing axons were localized in the developing frontal and parietal bones of the calvaria. Adrenergic innervation was not demonstrated in sutural tissue (superior sagittal, coronal or metopic) by this technique. To our knowledge, this study is the first to trace sympathetic nerve fibers in the rat calvaria by intra-axonal transport of HRP.

Structure-function relationships in rat brain stem subnucleus interpolaris. IX. Inputs from subnucleus caudalis

1. In an accompanying paper, Jacquin et al. (1990) described the effects of cortical ablation on the receptive-field (RF) properties of neurons in spinal trigeminal (SpV) subnucleus interpolaris (SpVi). A similar ablation paradigm was used here to clarify the role of an additional source of SpVi RF modulation, the extensive projection from caudally adjacent subnucleus caudalis (SpVc). 2. Intra- and extracellular recording, electrical stimulation, and RF mapping techniques were used to study the responses and projections of 356 SpVi cells in 11 rats 58-141 days after surgical isolation of SpVc from SpVi. This was achieved by a transverse knife cut through the lateral one-half of the left medulla just caudal to the obex. Because this lesion severs trigeminal (V) primary afferents caudal to SpVi, as well as postsynaptic intersubnuclear axons traversing to and from SpVi, kainic acid was used in other animals to selectively lesion SpVc inputs to SpVi. Seven rats received kainic acid injections into SpVc 5-28 days before providing similar electrophysiological data on 300 SpVi cells. Results were compared with that of 330 cells from 9 normal adult rats. 3. Knife-cut or kainic-acid lesions did not alter the topography of SpVi cells or the RF properties of 71 ipsilateral V primary afferents. However, both types of lesions produced the same profound changes in the response character of SpVi cells. Statistically reliable increases were found in the relative percentages of cells that 1) expressed convergence from multiple receptor organs, 2) were unresponsive to mechanical stimulation of orofacial regions, 3) responded tonically to a maintained peripheral stimulus, 4) were spontaneously active, 5) were directionally sensitive, 6) responded to stimulation of body surfaces innervated by cervical primary afferents, and 7) had split RFs. 4. RFs were also reliably larger for whisker-activated local circuit and projection neurons after both types of lesions. Over one-third of this local circuit group responded to more than one whisker in both experimental groups, whereas in normals all responded to one whisker. 5. All other SpVi response indices were unchanged by SpVc lesions. The most notable negative result was a normally low percentage of cells that were responsive to nociceptive stimuli. 6. To assess whether these RF changes reflected altered collateral morphology of V primary afferents in SpVi, whisker (n = 11) and guard-hair- (n = 7) activated axons were stained with horseradish peroxidase rostral to knife-cut or kainic-acid lesions.(ABSTRACT TRUNCATED AT 400 WORDS)

Developing retina and PNS segments for transplantation into the adult host eye: reconstruction of the mammalian visual system. 2. Results

The previous companion paper detailed a technique which allowed embryonic retinal ganglion cell axons to grow from the anterior eye chamber across a PNS bridge, and enter the adult host forebrain. Embryonic eyes of E11, E14, E18 and E21 animals were sutured to a PNS bridge, the embryonic eye implanted into an adult host eye, and the distal end of the bridge implanted into the host forebrain. Results indicate that when eyes of all ages are used for implantation, axons could be observed to grow from the embryonic retina, through the bridge and into the adult host forebrain. The axons extend for long distances in the host brain, reach various layers of the cortex and in a few animals enter the caudate/putamen complex. Control studies show that the bridge is used exclusively as the conduit to the brain, as opposed to the degenerated host optic nerve. Thus, the results presented in this paper indicate that successful grafting and transplantation is possible using the aforementioned technique. The results suggest that the described visual system reconstruction technique can be used for the study of development and transplantation in this system.

Developing retina and PNS segments for transplantation into the adult host eye: reconstruction of the mammalian visual system. 1. Methodology

Various techniques have been explored to determine the uses and limitations of techniques that enable the adult CNS to regenerate, but relatively little attention has been given to the consideration of a "reconstructed" visual system. Using this approach, one can design experiments to study the uses of exogenous tissues in reestablishing neuronal circuits that have been damaged. Toward this end, experiments were designed to determine whether embryonic retinal ganglion cells can project axons into a grafted PNS "bridge", and enter adult host targets that were partially deafferented. Embryonic eyes of E11, E14, E18 and E21 rats were sutured to peripheral nerve segments which served as bridges between the host eye and frontal cortex. Projections between the developing retina and the host brain could then be evaluated using HRP tracing techniques. From a methodological standpoint, the preparations are 65% effective; i.e., a viable bridge results between the embryonic eye and the host forebrain. The results presented in the accompanying paper demonstrate that the technique can yield results indicative of embryonic retinal development and axonal projection through the graft and into the host brain. This partial reconstruction of the visual system may prove a useful tool in understanding the uses and limitations of grafting in the CNS.

Renewed growth of identified brainstem axons into fetal cortical transplants in adult rat

Transplantation of fetal neocortex into the site of trigeminal brainstem injury induces regeneration of trigeminal primary afferent axons in adult rats. Renewed growth of injured primary afferent fibers into donor cortex can be extensive, though the innervation pattern does not resemble that normally seen in either brainstem or somatosensory cortex. Examination of the structural and functional characteristics of individual regenerate axon collaterals suggests that their morphology is determined by both intrinsic and postsynaptic target factors. Marked topographic alterations, however, question the utility of fetal cortical transplantation procedures in effecting functional recovery from brainstem injury.

Transplantation of brain tissue in the brain of rat. I. Growth characteristics of neocortical transplants from embryos of different ages

Differential growth of neural transplants as related to the age of the donor embryos was investigated in this study. Neocortical tissue of constant volume, obtained from embryos of 15, 16, 17, 18, 19, 20, and 21 days' gestational age, was transplanted into the cerebellum of 10-day-old rats. The fully grown transplants were analyzed quantitatively and qualitatively 90 days after transplantation. The ultimate volume of the transplants and the estimated total number of neurons in them followed a gradient in relation to the age of the donor embryos. At one extreme, the neural transplants from 15-day-old embryos grew very large, showing a 21-fold increase in size, and at the other extreme, those from 21-day-old embryos grew less than two-fold in volume. These differences were determined by the developmental history of the transplants. Neural tissue obtained from 15-day-old embryos contained predominantly neuroepithelial cells which continued to proliferate even after transplantation. This resulted in the large size of these transplants. At the other extreme, neural tissue from 21-day-old embryos contained predominantly preformed neuroblasts, and they simply differentiated afte transplantation. Due to this, the transplants were small in size. Neural tissues obtained from other embryos of different gestational ages between these two extremes contained neuroepithelial cells and preformed neuroblasts in differential ratios. The number of neuroepithelial cells in the transplants and their differential proliferative activity after transplantation, and the number of neuroblasts present, determined the differential sizes of these transplants. In histological preparations, all transplants were seen to contain normal-looking and well-differentiated neurons, and normal-looking neuropil. The transplants were integrated with the host brain, in that there was neither any gap nor any scar tissue between the transplants and the host neural tissue surrounding them. Neither the transplants nor the host brains showed any pathological reaction or neoplastic growth.

Transplantation of brain tissue in the brain of rat. II. Growth characteristics of neocortical transplants in hosts of different ages

In this study the growth of neural transplants was analyzed in relation to the age of the host animals and the site of transplantation. The influence of these two host parameters on the growth of neural transplants with high growth potential (tissue from 15-day-old embryos) and low growth potential (tissue from 18-day-old embryos) was investigated. Neocortical neural tissues of constant volume, obtained from 15- and 18-day-old embryos, were transplanted into the forebrain or cerebellum of 5-, 10-, 20-, 25-, 30-, 35- and 180-day-old host animals and analyzed, quantitatively well as qualitatively, 90 days after transplantation. The transplants grew larger in volume in the cerebellum than in the forebrain region of the hosts of all ages. In both sites, tissue from 15-day-old embryos yielded larger transplants than tissue from 18-day-old embryos. Transplants from 15-day-old embryos grew most extensively in 5-day-old host animals (33-fold in the cerebellum, and 23-fold in the forebrain region.) In older host animals it grew less extensively, and without much variation in size that could be attributed to the age of host animals. Tissue from 18-day-old embryos grew little, regardless of site of transplantation or age of host. Apparently the age of the host animals and the site of transplantation had greater influence on the growth of the neural transplants with high growth potential than on those with low growth potential. Histologically, the neural transplants in all cases contained normal-looking and fully differentiated neurons and were anatomically integrated with the host brain.

An aberrant nucleus in the telencephalon following administration of ENU during neuroembryogenesis

Administration of ENU to rats during embryonic development caused the emergence of aberrant nuclei in the dorsal telencephalon. They were located in the corpus callosum, and were composed of pyramidal and stellate neurons. This suggested that the aberrant nuclei arose out of the neurons of cerebral cortex that had failed to migrate during embryogenesis. The aberrant nuclei were found predominantly in the animals receiving ENU on day 18 or earlier of gestation.

Transplantation of neural tissues in the brains of laboratory mammals: technical details and comments

Various technical details on the transplantation of the embryonic neural tissues in the brains of the neonatal and adult rats are presented. Conditions determining successful or leading to unsuccessful survival, growth and differentiation of these transplants are critically examined.

N-ethyl-N-nitrosourea-induced teratogenesis of brain in the rat. A cellular and cytoarchitectural analysis of the neocortex

N-Ethyl-N-nitrosourea (ENU) was administered intravenously to pregnant Wistar-albino rats on days 14--21 of gestation in order to study the teratological effects of the carcinogen on the developing brain. Offspring were killed 60 days postnatally, and the brains examined histologically by cresyl violet staining and Golgi-Cox preparations. Macroscopic examination of the brains revealed a graded pattern of microcephaly. Injection of ENU on day 14 of gestation gave the most severe effects and injection on day 21 the least effects. Microscopic examination of the neocortex revealed a graded reduction in the lateral and sagittal lengths, thickness, and the number of cells in a sample slab of the cortex. In the Golgi-Cox preparations the pyramidal neurons of cortical layers III and V, as well as neurons of other layers, were seen to have fewer secondary and tertiary dendrites, and the length of their dendrites appeared stunted. These characteristics also were graded in relation to the day of injection of ENU. Altered cytology and cytoarchitecture of the neocortex and possible underlying mechanisms are discussed.

Transplantation of brain tissue in the brain of adult rats

Brain tissues obtained from rat embryos were transplanted in the forebrain and/or cerebellum of the adult rats. The transplants survived, grew and achieved normal cellular and cytoarchitectural differentiation. They had become anatomically integrated with the host brain. The animals did not show any obviously detectable abnormal behavior or pathology of the brain. The transplants survived as long as the animals did suggesting that they had become a part and parcel of the host brain.