Reproducible sampling regimen for specific cortical regions: application to speech-associated areas

Neural correlates in the processing of phoneme-level complexity in vowel production

We investigated how articulatory complexity at the phoneme level is manifested neurobiologically in an overt production task. fMRI images were acquired from young Korean-speaking adults as they pronounced bisyllabic pseudowords in which we manipulated phonological complexity defined in terms of vowel duration and instability (viz., COMPLEX: /tiɯi/ >> MID-COMPLEX: /tiye/ >> SIMPLE: /tii/). Increased activity in the left inferior frontal gyrus (Brodmann Areas (BA) 44 and 47), supplementary motor area and anterior insula was observed for the articulation of COMPLEX sequences relative to MID-COMPLEX; this was the case with the articulation of MID-COMPLEX relative to SIMPLE, except that the pars orbitalis (BA 47) was dominantly identified in the Broca's area. The differentiation indicates that phonological complexity is reflected in the neural processing of distinct phonemic representations, both by recruiting brain regions associated with retrieval of phonological information from memory and via articulatory rehearsal for the production of COMPLEX vowels. In addition, the finding that increased complexity engages greater areas of the brain suggests that brain activation can be a neurobiological measure of articulo-phonological complexity, complementing, if not substituting for, biomechanical measurements of speech motor activity.

Broca's region: novel organizational principles and multiple receptor mapping

There is a considerable contrast between the various functions assigned to Broca's region and its relatively simple subdivision into two cytoarchitectonic areas (44 and 45). Since the regional distribution of transmitter receptors in the cerebral cortex has been proven a powerful indicator of functional diversity, the subdivision of Broca's region was analyzed here using a multireceptor approach. The distribution patterns of six receptor types using in vitro receptor autoradiography revealed previously unknown areas: a ventral precentral transitional cortex 6r1, dorsal and ventral areas 44d and 44v, anterior and posterior areas 45a and 45p, and areas op8 and op9 in the frontal operculum. A significant lateralization of receptors was demonstrated with respect to the cholinergic M(2) receptor, particularly in area 44v+d. We propose a new concept of the anterior language region, which elucidates the relation between premotor cortex, prefrontal cortex, and Broca's region. It offers human brain homologues to the recently described subdivision of area 45, and the segregation of the ventral premotor cortex in macaque brains. The results provide a novel structural basis of the organization of language regions in the brain.

The left human speech-processing cortex is thinner but longer than the right

We present histological data from 21 post-mortem, adult human cases that indicate the neocortex on the left planum temporale (secondary auditory cortex) is thinner but longer than that on the right side. The volumes of the left and right regions are approximately equal. Thus, the left planum temporale cortex is long and thin and the right short and thick. The present data fit excellently with previous studies of the volume, surface area, cytoarchitectonics, and neuronal structures of these areas. From these studies we suggest that the hemispheric differences arise from a so-called "balloon model" of cortical development. In this the cortex is extended and stretched by white matter growth. The stretching is greater on the left side, leaving greater distances between neuronal columns and more tangentially (to the pial surface) oriented dendrites on that side. This difference in fine structure can result in more independent activity of individual columns on the left, and could be an anatomical factor in the usual dominance of the left hemisphere for speech perception (Seldon, 1982, 1985).

MRI diffusion tensor tracking of a new amygdalo-fusiform and hippocampo-fusiform pathway system in humans

PURPOSE

To use MRI diffusion-tensor tracking (DTT) to test for the presence of unknown neuronal fiber pathways interconnecting the mid-fusiform cortex and anteromedial temporal lobe in humans. Such pathways are hypothesized to exist because these regions coactivate in functional MRI (fMRI) studies of emotion-valued faces and words, suggesting a functional link that could be mediated by neuronal connections.

MATERIALS AND METHODS

A total of 15 normal human subjects were studied using unbiased DTT approaches designed for probing unknown pathways, including whole-brain seeding and large pathway-selection volumes. Several quality-control steps verified the results.

RESULTS

Parallel amygdalo-fusiform and hippocampo-fusiform pathways were found in all subjects. The pathways begin/end at the mid-fusiform gyrus above the lateral occipitotemporal sulcus bilaterally. The superior pathway ends/begins at the superolateral amygdala. The inferior pathway crosses medially and ends/begins at the hippocampal head. The pathways are left-lateralized, with consistently larger cross-sectional area, higher anisotropy, and lower minimum eigenvalue (D-min) on the left, where D-min assesses intrinsic cross-fiber diffusivity independent of curvature.

CONCLUSION

A previously-undescribed pathway system interconnecting the mid-fusiform region with the amygdala/hippocampus has been revealed. This pathway system may be important for recognition, memory consolidation, and emotional modulation of face, object, and lexical information, which may be disrupted in conditions such as Alzheimer's disease.

Distribution of brain atrophy in behavioral variant frontotemporal dementia

Marked brain atrophy occurs in frontotemporal dementia (FTD) yet substantial variation between cases is seen. Recently, a four-level staging scheme which reflects increasing disease duration, severity of dementia and degree of neurodegeneration was described. In the present study, the extent and magnitude of atrophy in behavioral variant FTD and its relationship to disease duration and pathological subtype was further evaluated by quantifying the volume of 30 anatomically-defined regions. A validated point count technique was applied to 17 patients with FTD (9 Pick's disease, 6 dementia lacking distinctive histology, 2 FTD with motor neuron disease) and 21 controls. Atrophy was seen in all brain regions except the inferior frontal cortex and area 37. As might be expected, increasing severity of atrophy occurred with increasing disease duration and stage however measurable atrophy was more widespread than indicated by the staging scheme. Furthermore, severity of atrophy was not related to pathological subtype. Frontal, limbic and temporal regions appeared to be severely affected early in the disease process with temporal lobe atrophy the best predictor of disease duration. White matter, more posterior regions and the subcortex were affected later in the disease. These findings demonstrate a pattern of selective vulnerability which progresses over time. Furthermore, they demonstrate that although patients with a similar clinical subtype may have differing underlying histopathology, the pattern, severity and progression of brain atrophy is the same. This suggests that the regional pattern of neurodegeneration, rather than the type of histopathology influences the clinical syndrome in FTD.

Volume estimation of prefrontal cortical subfields using MRI and stereology

The objective of this protocol was to provide a rapid, neurofunctionally relevant alternative to region-drawing or automated gyral/sulcal-based techniques. The Cavalieri method and point counting [e.g. Br. J. Radiol. 73 (2000) 679] were used in conjunction with a previously established parcellation methodology [Arch. Gen. Psychiatry 57 (2000) 761] to estimate the volumes of anatomically defined subfields of the prefrontal cortex (PFC) based on landmarks visible on T(1)-weighted magnetic resonance (MR) images. Ten participants (n=5 healthy adults; n=5 patients) were studied. Regional PFC volume estimates derived from point counting methods were reproducible between raters (Intraclass Correlations (ICC)=0.92-0.95) and repeatable within rater (ICC=0.93-0.99). Predicted coefficients of error for individual volume estimates were less than 5%. This protocol provides an efficient means of calculating unbiased volume estimates of the PFC with predictable precision for use in both cognitive and clinical studies.

Selective loss of pyramidal neurons in the pre-supplementary motor cortex in Parkinson's disease

The nonprimary motor cortices have not previously been studied in Parkinson's disease, despite the selective pattern of dysfunction observed in these regions. In particular, the pre-supplementary motor region is consistently underactive, with successful treatments correlating with increased excitatory drive to nonprimary motor regions. This finding could suggest a primary cortical abnormality in the pre-supplementary motor area (pre-SMA) in Parkinson's disease. We analysed and compared neuronal number in the pre-SMA and dorsolateral premotor cortical regions in 5 cases of Parkinson's disease and 5 controls. For each cortical region, the total neuronal number as well as the estimated numbers of subpopulations of interneurons and pyramidal neurons was quantified using previously published unbiased techniques. The results showed a significant loss of cortico-cortical projecting pyramidal neurons in the pre-SMA with no loss of other pyramidal neurons or interneurons either in this region or in the dorsolateral premotor region. These findings indicate a highly selective loss of pyramidal cells in the pre-SMA in Parkinson's disease, consistent with previous imaging findings in this disease. Our results implicate the degeneration of the premotor projection from the pre-SMA, along with dopaminergic basal ganglia dysfunction, in the pathogenesis of Parkinson's disease.

Pyramidal Cell Loss in Motor Cortices in Huntington's Disease

Patterns of huntingtin protein aggregation and cortical neuronal loss suggest early involvement of corticostriatal pathways in Huntington's disease. However, theories of pathogenesis of chorea rely on the motor cortices being intact. The motor cortices have not previously been studied at a cellular level in Huntington's disease. We analyzed the neuronal number in the caudate, putamen, and three motor cortical areas in five cases of Huntington's disease and five controls. For each motor cortical region the total neuronal number, number of interneurons, and number of SMI32 immunopositive pyramidal neurons were quantified using previously published techniques and any relationship between cell loss and severity or duration of chorea was examined. The results showed a loss of long projecting SMI32 immunopositive pyramidal neurons in the primary motor cortex with associated morphological changes and suggest a loss of short projecting pyramidal neurons in the premotor cortex. Degeneration in the primary motor cortex correlated with subcortical degeneration. These findings indicate pyramidal cell involvement in Huntington's disease and implicate the degeneration of corticostriatal pathways in the production of chorea.

Cortical degeneration associated with phonologic and semantic language impairments in AD

OBJECTIVE

To compare the pattern of cortical degeneration associated with different language deficits in cases of AD.

METHODS

Cases for detailed neuropathologic analysis (Patients 1 and 2) were selected because of their detailed clinical and neuropsychological assessments of language dysfunction in AD. Patient 1 had severe phonologic impairment with relatively preserved semantic aspects of language. Patient 2 had severe semantic language impairment with relatively preserved phonologic skills. The tissue volume of cortical regions associated with speech and language function was measured using standardized three-dimensional techniques. Neuronal areal fraction was also measured from histologic tissue samples. The degree of volume atrophy and neuronal loss was calculated in comparison to control measures (n = 10 men and 11 women). Measurements more than 2 SD from controls were considered abnormal.

RESULTS

Both AD cases had significant degeneration of the superior temporal gyrus and area 37. Cortical language regions affected only in Patient 1 included the anterior and posterior insula and part of Broca's area. In contrast, Patient 2 had a greater degree of degeneration in the temporal gyri and their white matter connections with the hippocampal/entorhinal complex.

CONCLUSIONS

Variable patterns of neurodegeneration underlie the clinical differences observed in patients with AD. Disconnection within the temporal lobe appears associated with semantic language difficulties, whereas disconnection of the anterior and posterior language areas appears associated with phonologic and grammatical impairment.

Specific temporoparietal gyral atrophy reflects the pattern of language dissolution in Alzheimer's disease

The aim of this study was to determine the topography and degree of atrophy in speech and language-associated cortical gyri in Alzheimer's disease. The post-mortem brains of 10 patients with pathologically confirmed Alzheimer's disease and 21 neurological and neuropathological controls were sectioned in serial 3 mm coronal slices and grey and white matter volumes were determined for specific cortical gyri. All Alzheimer's disease patients had prospectively documented impairments in verbal and semantic memory with concomitant global decline. The cortical regions of interest included the planum temporale, Heschl's gyri, the anterior superior temporal gyri, the middle and inferior temporal gyri, area 37 at the inferior temporoparietal junction, areas 40 and 39 (supramarginal and angular gyri) and Broca's frontal regions. Although most patients had end-stage disease, the language-associated cortical regions were affected to different degrees, with some regions free of atrophy. These included Broca's regions in the frontal lobe and Heschl's gyri on the superior surface of the temporal lobe. In contrast, the inferior temporal and temporoparietal gyri (area 37) were severely reduced in volume. The phonological processing regions in the superior temporal gyri (the planum temporale) were also atrophic in all Alzheimer's disease patients while the anterior superior temporal gyri were only atrophic in female patients. Such atrophy may underlie the more severe language impairments previously described in females with Alzheimer's disease. The present study is the first to analyse the volumes of language-associated gyri in post-mortem patients with confirmed Alzheimer's disease. The results show that atrophy is not global but site-specific. Atrophied gyri appear to reflect a specific network of language and semantic memory dissolution seen in the clinical features of patients with Alzheimer's disease. Females showed greater atrophy than males in the anterior superior temporal gyri.

The cerebral cortex is damaged in chronic alcoholics

There is some controversy in the literature concerning whether chronic alcohol consumption damages the cerebral cortex. While decreased neuronal density in specific cortical regions is well described in chronic alcoholics, a recent study by Badsberg Jensen and Pakkenberg using unbiased stereological methods questions whether neurodegeneration occurs. In order to assess selective neurodegeneration in the cerebral cortex of chronic alcoholics, regional volumes and unbiased estimates of regional neuronal number (including neuronal identification with calcium-binding proteins) were calculated for 14 chronic alcoholics and 21 controls. Cases were carefully screened to exclude any interfering pathologies. Lifetime and maximum daily alcohol consumption was determined, and homogeneous groups were identified (four chronic alcoholics with Wernicke's encephalopathy and Korsakoff's psychosis, four chronic alcoholics with Wernicke's encephalopathy alone, six chronic alcoholics without Wernicke's encephalopathy or Korsakoff's psychosis, and 21 controls). Brain volume analysis revealed that discrete regions were significantly smaller in the chronic alcoholics compared to controls. As previously shown, white matter regions (particularly in the frontal lobe) were the most significantly reduced in volume. Alcoholics with Wernicke's encephalopathy (either alone or in combination with Korsakoff's psychosis) had significantly smaller white matter volumes than controls or alcoholics without these complications. Medial temporal lobe regions and the thalamus were also reduced in volume. Regression analyses revealed that the volume of both the white matter and thalamus negatively correlated with alcohol consumption. Consistent with the interpretation of previous neuronal density studies, selective neuronal loss was found in the superior frontal association cortex of chronic alcoholics, while no loss occurred from the motor cortex. The number of parvalbumin-, calbindin- and calretinin-immunoreactive neurons was found to be unaltered in chronic alcoholics, suggesting that the neurodegeneration is confined to the non-GABAergic pyramidal neurons. As neurodegeneration was observed in all alcoholic groups, damage to the frontal association cortex is not restricted to alcoholics with the amnesia of Korsakoff's psychosis. These results are consistent with the notion that chronic alcohol consumption is associated with selective neuronal vulnerability. The selective frontal neurodegeneration and the frontal focus of white matter atrophy are supported by neuropsychological, regional blood flow, and magnetic resonance imaging studies of frontal lobe dysfunction in chronic alcoholics and may correlate with abnormalities in working memory.

Cell loss in the nucleus basalis is related to regional cortical atrophy in Alzheimer's disease

Cortical atrophy and cell loss in the cholinergic nucleus basalis is a well-established characteristic of Alzheimer's disease; however, previous studies not have analysed cholinergic cell loss and cortical atrophy in concert. In autopsy brains from eight patients with Alzheimer's disease and 12 control subjects, the numbers of nucleus basalis neurons were determined from 50-microm serial Nissl-stained sections. Volumes of the cerebrum, cortical gray matter (total, lobar and subregional), white matter and deep gray structures were computed by point counting on black and white photographs of gapless 3-mm coronal slices of formalin-fixed brains. Cell loss in the nucleus basalis was found to range between 89% and 42% in Alzheimer's disease compared with controls. White matter volume was unchanged in absolute terms in Alzheimer's disease patients compared with controls, while cortical volume was significantly reduced. Gray matter atrophy was most prominent in temporal and frontal cortices. A highly significant linear relationship was found between cortical volume and nucleus basalis cell number in controls and Alzheimer's disease patients, with values for both groups on a single regression line. Whole brain and cerebral volumes were also highly correlated to nucleus basalis cell numbers in both groups. A quantitative analysis of plaque and tangle burden in cortical target areas of the nucleus basalis was performed. In contrast to the relationship with cortical volume, nucleus basalis cell number and neurofibrillary tangle number were not significantly correlated to the density of cortical histopathology. These results suggest that the volume of cortical gray matter is coupled to the number of nucleus basalis neurons. Compromised viability of nucleus basalis neurons may precede cortical volume loss as large numbers of neurofibrillary tangles, detected with nickel peroxidase staining, were found in this nucleus in all Alzheimer's disease cases, including those with minimal cell loss.

Chronic alcohol consumption does not cause hippocampal neuron loss in humans

High alcohol consumption for long periods of time causes significant hippocampal neurodegeneration in rodents. A single study using neuronal density measures has reported similar findings in humans. The present study aims to substantiate these findings in human alcoholics using unbiased stereological techniques. Both amnesic (n = 5) and nonamnesic (n = 7) chronic alcoholics were selected and compared with nonalcoholic controls (n = 8) and patients with marked memory loss and hippocampal neurodegeneration caused by Alzheimer's disease (n = 4). Hippocampal volume was significantly reduced in the alcoholics and in patients with Alzheimer's disease. However, in alcoholics the volume reduction occurred exclusively in the white matter, whereas both the gray and white matter were reduced in the patients with Alzheimer's disease. Neuron loss occurred exclusively from the CA1 and subiculum subregions of the hippocampus in Alzheimer's disease. No neuron loss occurred from any subregion of the hippocampus in alcoholics. There were no correlations with age and any of the volume or neuron number measures. Hippocampal volume correlated with brain volume and with the regional gray and white matter volumes within the hippocampus. In addition, hippocampal gray matter volume correlated with the number of CA1 pyramidal neurons. These results do not support the theory that chronic alcohol consumption is neurotoxic to hippocampal pyramidal neurons in humans. Further, the present results suggest that changes observed in rodent models of alcoholism do not parallel those observed in humans, questioning the validity of such models.