Thomas L. Kemper

Histoanatomic observations of the brain in early infantile autism

Early infantile autism is a behaviorally defined syndrome that is often associated with abnormalities on neurologic examination and seizures. We report on the brain of a 29-year-old autistic man as compared with that of an age- and sex-matched normal control, using gapless sections of whole brain. Abnormalities were found in the hippocampus, subiculum, entorhinal cortex, septal nuclei, mamillary body, selected nuclei of the amygdala, neocerebellar cortex, roof nuclei of the cerebellum, and inferior olivary nucleus.

Localization of white matter volume increase in autism and developmental language disorder

Increased brain volume in autism appears to be driven mainly by an unexplained white matter enlargement, and we have reported a similar phenomenon in developmental language disorder (DLD). Localization of this enlargement would strongly guide research into its cause, tissue basis, and functional implications. We utilized a white matter parcellation technique that divides cerebral white matter into an outer zone containing the radiate compartment and an inner zone containing sagittal and bridging system compartments. In both high‐functioning autism and DLD, enlargement localized to the radiate white matter (all lobes in autism, all but parietal in DLD), whereas inner zone white matter compartments showed no volume differences from controls. Furthermore, in both autism and DLD, later or longer‐myelinating regions showed greater volume increases over controls. Neither group showed cerebral cortex, corpus callosum, or internal capsule volume differences from control. Radiate white matter myelinates later than deep white matter; this pattern of enlargement thus is consistent with striking postnatal head circumference percentile increases reported in autism. These findings suggest an ongoing postnatal process in both autism and DLD that is probably intrinsic to white matter, that primarily affects intrahemispheric and corticocortical connections, and that places these two disorders on the same spectrum.

Consensus Paper: Pathological Role of the Cerebellum in Autism

There has been significant advancement in various aspects of scientific knowledge concerning the role of cerebellum in the etiopathogenesis of autism. In the current consensus paper, we will observe the diversity of opinions regarding the involvement of this important site in the pathology of autism. Recent emergent findings in literature related to cerebellar involvement in autism are discussed, including: cerebellar pathology, cerebellar imaging and symptom expression in autism, cerebellar genetics, cerebellar immune function, oxidative stress and mitochondrial dysfunction, GABAergic and glutamatergic systems, cholinergic, dopaminergic, serotonergic, and oxytocin-related changes in autism, motor control and cognitive deficits, cerebellar coordination of movements and cognition, gene–environment interactions, therapeutics in autism, and relevant animal models of autism. Points of consensus include presence of abnormal cerebellar anatomy, abnormal neurotransmitter systems, oxidative stress, cerebellar motor and cognitive deficits, and neuroinflammation in subjects with autism. Undefined areas or areas requiring further investigation include lack of treatment options for core symptoms of autism, vermal hypoplasia, and other vermal abnormalities as a consistent feature of autism, mechanisms underlying cerebellar contributions to cognition, and unknown mechanisms underlying neuroinflammation.

Hippocampus in autism : a Golgi analysis

Abstract Autism is a behaviorally defined syndrome in which neuropathological abnormalities have been identified in the limbic system and cerebellum. The morphology of hippocampal neurons in two cases of infantile autism was studied and compared to age-matched controls. CA4 neurons in autistic children were smaller in perikaryon area and dendritic branching of both CA4 and CA1 neurons was less than in controls. These findings are consistent with previous studies and suggest a curtailment in maturation in the pathogenesis of autism.

Neurobiological Bases of Age-Related Cognitive Decline in the Rhesus Monkey

The rhesus monkey offers a useful model of normal human aging because when monkeys are tested on a battery of behavioral tasks that can also be used to evaluate cognition in humans, it is found that the monkeys undergo an age-related decline in several domains of cognitive function as do humans. In monkeys these changes begin at about 20 years of age. To determine what gives rise to this cognitive decline, we have examined several parameters in the brains of monkeys. Some parameters do not change with age. Examples of this are the numbers of neurons in the neocortex and hippocampal formation, and the numbers of synapses in the hippocampal formation. Changes in other parameters can be positively correlated with chronological age; examples of this are numbers of neuritic plaques, a decrease in the numbers of neurons in the striatally projecting pars compacta of the substantia nigra, and a decrease in the thickness of layer I in primary visual cortex. But the most interesting changes are those that correlate either with cognitive decline alone, or with both cognitive decline and chronological age. Among these are a breakdown in the integrity of myelin around axons, an overall reduction in the volume of white matter in the cerebral hemispheres, thinning of layer I in area 46 of prefrontal cortex, and decreases in the cell density in cortically projecting brain stem nuclei. To date then, our studies suggest that the cognitive declines evident in the rhesus monkey may be a consequence of changes in layer I and in the integrity of myelinated axons, rather than an agerelated loss of cortical neurons or synapses, as has long been assumed.

Density and Distribution of Hippocampal Neurotransmitter Receptors in Autism: An Autoradiographic Study*

Neuropathological studies in autistic brains have shown small neuronal size and increased cell packing density in a variety of limbic system structures including the hippocampus, a change consistent with curtailment of normal development. Based on these observations in the hippocampus, a series of quantitative receptor autoradiographic studies were undertaken to determine the density and distribution of eight types of neurotransmitter receptors from four neurotransmitter systems (GABAergic, serotoninergic [5-HT], cholinergic, and glutamatergic). Data from these single concentration ligand binding studies indicate that the GABAergic receptor system (3[H]-flunitrazepam labeled benzodiazepine binding sites and 3[H]-muscimol labeled GABAA receptors) is significantly reduced in high binding regions, marking for the first time an abnormality in the GABA system in autism. In contrast, the density and distribution of the other six receptors studied (3[H]-8OH-DPAT labeled 5-HT1A receptors, 3[H]-ketanserin labeled 5-HT2 receptors, 3[H]-pirenzepine labled M1 receptors, 3[H]-hemicholinium labeled high affinity choline uptake sites, 3[H]-MK801 labeled NMDA receptors, and 3[H]-kainate labeled kainate receptors) in the hippocampus did not demonstrate any statistically significant differences in binding.

Nucleus raphe dorsalis in dementia of the Alzheimer type: neurofibrillary changes and neuronal packing density.

Within the reticulate core of the brain the nucleus raphe dorsalis (NRD) is a major site of predilection for the neurofibrillary tangle (NFT) in dementia of the Alzheimer type (DAT) and, according to some studies, its primary brain stem site. In a quantitative study we have shown in six aged control brains an average of 5.2 NFT per histological section or 25.8 per mm3 and in seven age-matched brains with DAT a highly significant six-fold increase, respectively 35.3 NFT per histological section or 188.5 per mm3. There was no significant difference between the two groups in overall neuronal cell packing density. There was, however, a significant decrease in a subpopulation of neurons in DAT, a large polygonal neuron. Despite the prominence of the NRD as a target for NFT, the actual proportion of affected NRD cells was small, 0.35% in controls and 2.25% in DAT.

Cerebellar Purkinje Cells are Reduced in a Subpopulation of Autistic Brains: A Stereological Experiment Using Calbindin-D28k

Although a decreased number of cerebellar Purkinje cells (PCs) in the autistic brain has been widely reported with a variety of qualitative and quantitative methods, the more accurate method of cell counting with modern stereology has not yet been employed. An additional possible problem with prior reports is the use of Nissl staining to identify the PCs, as this can miss cells due to staining irregularities. In the present study, PCs were immunostained for calbindin-D28k (CB), as this has been shown to be a more reliable marker for PCs than the Nissl stain, with more than 99% of the PCs immunopositive (Whitney, Kemper, Rosene, Bauman, Blatt, J Neurosci Methods 168:42–47, 2008). Using stereology and CB immunostaining, the density of PCs was determined in serial sections from a consistently defined area of the cerebellar hemisphere in four control and six autistic brains, with the density of PCs then correlated with the clinical severity of autism. Overall, there was no significant difference in the density of PCs between the autistic and control groups. However, three of six autistic brains had PC numbers that fell within the control range, whereas the remaining three autistic brains revealed a reduction compared with the control brains. These data demonstrate that a reduction in cerebellar PCs was not a consistent feature of these autistic brains and that it occurred without discernible correlation between their density and the clinical features or severity of autism.

Down's syndrome Is there a decreased population of neurons?

Although gross abnormalities have been described in the brains of patients with Downs syndrome (DS), microscopic studies have revealed only minor and inconsistent findings. We compared two DS brains, in whole-brain serial sections, with similarly prepared age- and sex-matched normal controls. Architectonic abnormalities were noted, and cell counts revealed a significant poverty of granular cells in the DS brains, particularly in granular fields such as areas 3,17, and 41. Golgi studies demonstrated all major cell types. A striking feature of the brain morphology in DS may be the curtailment of a specific cell type, most likely the aspinous stellate.

The anterior cingulate cortex in autism: heterogeneity of qualitative and quantitative cytoarchitectonic features suggests possible subgroups

Autism is a behaviorally defined disorder with deficits in social interaction, communication, atypical behaviors, and restricted areas of interest. Postmortem studies of the brain in autism have shown a broad spectrum of abnormalities in the cerebellum and neocortex, involving limbic regions such as anterior cingulate cortex (ACC, Brodmann’s area 24). Using stereological techniques, we analyzed quantitatively cytoarchitectonic subdomains of the ACC (areas 24a, b, c) with regard to cell packing density and cell size. Microscopic examination of the ACC was also done to identify any neuropathologies. Results showed a significant decrease in cell size in layers I–III and layers V–VI of area 24b and in cell packing density in layers V–VI of area 24c. Direct comparisons revealed irregular lamination in three of nine autism brains and increased density of neurons in the subcortical white matter in the remaining cases. Because previous studies have suggested that von Economo neurons (VENs) may be altered in autism, a preliminary study of their density and size was undertaken. VEN density did not differ between autism and control brains overall. However, among the nine autism cases, there were two subsets; three brains with significantly increased VEN density and the remaining six cases with reduced VEN density compared to controls. Collectively, the findings of this pilot study may reflect the known heterogeneity in individuals with autism and variations in clinical symptomotology. Further neuroanatomic analyses of the ACC, from carefully documented subjects with autism, could substantially expand our understanding of ACC functions and its role in autism.