Anatomical connectivity defines the organization of clusters of cortical areas in the macaque monkey and the cat

The number of different cortical structures in mammalian brains and the number of extrinsic fibres linking these regions are both large. As with any complex system, systematic analysis is required to draw reliable conclusions about the organization of the complex neural networks comprising these numerous elements. One aspect of organization that has long been suspected is that cortical networks are organized into 'streams' or 'systems'. Here we report computational analyses capable of showing whether clusters of strongly interconnected areas are aspects of the global organization of cortical systems in macaque and cat. We used two different approaches to analyse compilations of corticocortical connection data from the macaque and the cat. The first approach, optimal set analysis, employed an explicit definition of a neural 'system' or 'stream', which was based on differential connectivity. We defined a two-component cost function that described the cost of the global cluster arrangement of areas in terms of the areas' connectivity within and between candidate clusters. Optimal cluster arrangements of cortical areas were then selected computationally from the very many possible arrangements, using an evolutionary optimization algorithm. The second approach, non-parametric cluster analysis (NPCA), grouped cortical areas on the basis of their proximity in multidimensional scaling representations. We used non-metric multidimensional scaling to represent the cortical connectivity structures metrically in two and five dimensions. NPCA then analysed these representations to determine the nature of the clusters for a wide range of different cluster shape parameters. The results from both approaches largely agreed. They showed that macaque and cat cortices are organized into densely intra-connected clusters of areas, and identified the constituent members of the clusters. These clusters reflected functionally specialized sets of cortical areas, suggesting that structure and function are closely linked at this gross, systems level.     

Substance P-immunoreactive neurons in the brainstem of the cat related to cardiovascular centers

Summary The distribution of substance P-immunoreactivity (SP-IR) in the brainstem and spinal cord of normal and colchicine-pretreated cats was analysed using the peroxidase-antiperoxidase (PAP) technique. Numerous SP-IR fibers are present in the nucleus solitarius, nucleus dorsalis nervi vagi and nucleus spinalis nervi trigemini, various parts of the formatio reticularis, substantia grisea centralis mesencephali, locus coeruleus and nucleus parabrachialis. SP-IR perikarya occur in the substantiae gelatinosa and intermedia of the spinal cord, the nucleus spinalis nervi trigemini-pars caudalis, the nucleus dorsalis nervi vagi, and the nucleus solitarius, as well as in the adjacent formatio reticularis and the medullary nuclei of the raphe. In addition, SP-IR cell bodies are located in the nuclei raphe magnus and incertus, ventral and dorsal to the nucleus tegmentalis dorsalis (Gudden), nucleus raphe dorsalis, substantia grisea centralis mensencephali, locus coeruleus, nucleus parabrachialis and colliculus superior.The results indicate that SP-IR neurons may be involved in the regulation of cardiovascular functions both at the central and peripheral level. A peripheral afferent portion seems to terminate in the nucleus solitarius and an efferent part is postulated to originate from the nucleus dorsalis nervi vagi and from the area of the nuclei retroambiguus, ambiguus and retrofacialis.     

Organization of somatic nerve projections in various cortical areas of the cat cerebellum

We conducted a layer analysis of evoked potentials arising in various cortical cerebellar areas (vermis and intermediate zones of the anterior lobe, and the ansiform lobe) of non-anesthetized cats upon stimulation of nerves in fore- and hindlimbs. This analysis yielded the conclusion on the arrival of stimuli at the cerebellar cortex over two types of moss fibers innervating two types of granule cells which we described earlier. Impulses transmitted over type I moss fibers stimulate Purkinje cells. The activation of type II moss fibers has no immediate effect on these cells. Type I moss fibers terminate in the vermis and the intermediate zone of the hemispheres and do not terminate in the lateral hemispheric region. While projections of type I moss fibers are somatotopically organized in the intermediate zone they are diffuse in the vermis. Type II moss fibers terminate in all the regions of the crebellar cortex under study, but their projections show no somatotopic organization. The question of the afferent pathways terminating as type I and II moss fibers is discussed.Institute of Problems of Information Transmission, Academy of Sciences of the USSR, Moscow. M. V. Lomonosov Moscow State University. Translated from Neirofiziologiya, Vol. 3, No. 2, pp. 166–174, March–April, 1971.     

A quantitative stereological study of the area of cortical surface in the monkey, pig and cat cerebrum

An unbiased stereological method (the 'vertical section') has been available since the 1980s for the area estimation of an arbitrary surface. Using this methodology, the ratio of the inner (folded) cerebral cortical surface area, to that of the outer surface, was estimated to be about 2 in Man. We have used the same morphometric techniques to study the cerebrum of seven monkeys, six pigs and six cats. The results demonstrated that the ratios were similar in monkeys (1.22 +/- 0.21, SD) and pigs (1.00 +/- 0.22), and that both were significantly larger than the ratio in cats (0.71 +/- 0.18).     

Projections of the cortical visual areas of the posterior gyrus sigmoid and the caudate nucleus in the cat

The complex performances of the visuo-motor system entail probably an intervention of circuits connecting, the primary visual areas, to other cortical regions, specially the sensory motor cortex, and certain sub-cortical formations. For testing this hypothesis, the unilateral resection of the areas 17, 18 and 19 has been undertaken on 19 cats, with delays ranging from 8 days to 3 months after intervention. The tracing of the pathways was carried out by combining different degenerating methods in particular the Marchi reaction. Based on this, it is possible to define a compact bundle of the axons originating from the primary visual cortex and dividing into two fascicles of unequal magnitude. The slender ends in the lower part of the posterior gyrus sigmo?d; the larger one penetrates into the caudale nucleus. An ultrastructural study specifies the modalities of distribution of the axons within this nucleus.     

Dynamic mechanism of visual accommodation in teleosts: structure of the lens muscle and its nerve control

The accommodatory system was examined in two teleosts (mackerel and bass). The fine structure and innervation of the lens muscle is presented to characterize the muscle organization. The neural pathway involved in the dynamic accommodation was examined by analysing the fibre spectrum of the ciliary nerve, and the nerve that controls the lens-muscle activity was studied by means of electrical stimulation. The lens muscle is composed of smooth-muscle cells, which contain numerous mitochondria. Many synaptic endings are also found on the muscle cells; these synaptic endings contain many agranular vesicles. From the results of the fibre analysis, it was found that the nerve that controls the lens muscle contains less than 100 myelinated nerve fibres in both fish: the electrical stimulation experiments demonstrate that the muscle is controlled by oculomotor (parasympathetic) nerve fibres. Ultrastructural features of the lens muscle and its nerve control resemble those of the mammalian ciliary muscle. The teleostean lens muscle is classified as a multi-unit smooth muscle.     

Spinal projections of brainstem respiratory related neurons in the cat as revealed by retrograde fluorescent markers

By means of retrograde axonal transport of fluorescent tracers, connections between brainstem respiratory related regions and the spinal cord has been studied in the cat. Neurons at the pneumotaxic center project bilaterally (90% ipsi-, 10% contra-) to cervical and lumbar spinal cord and ipsilaterally to thoracic levels. The ventrolateral nucleus of the tractus solitarius project mainly contralaterally (85%) to cervical levels and only contralaterally to thoracic levels; no efferent projections were found to lumbar levels. The ventral respiratory group showed a great number of neurons projecting to the spinal cord especially from the nucleus retroambiguus. Both nuclei, ambiguus and retroambiguus, project mainly contralaterally (70%) to the spinal cord. The B?tzinger complex showed rather scarce bilateral projections to cervical and only ipsilateral projections to lower cervical, thoracic and lumber levels.     

Growth related changes to functional parameters in the bovine lens.

Dimensions, volumes and protein contents were measured for bovine lenses with wet weights ranging from 0.17-3.07 g (2 months gestation to 19 years post-natal). All increase in a non-linear fashion. The lens becomes flatter with age due to a more rapid increase in the equatorial plane, but the ratio of anterior to posterior sagittal distances remains constant (1.19). The radius of curvature increases from 4.9 to 15 for the anterior surface and from 4.4 to 13 for the posterior. Protein content increases more rapidly than volume resulting in an increased average protein concentration from around 18% in the early prenatal lens to nearly 50% in the 19 year old. Total protein content (TPC) was found to be related to wet weight (We) according to the equation, TPC = 0.3We1.33. It is suggested that TPC is a better parameter for describing growth than wet weight or age. The refractive index, in the equatorial plane, increases towards the centre, from 1.38 at the edge of the lens. The maximum index, in the centre, increases with lens size up to 1.474 in the largest lens studied. This corresponds to a protein concentration of 70%. In all lenses, refractive index and protein concentration gradients were superimposable when plotted from the outside towards the centre. The optical performance of the lenses was assessed by measuring the back focal length which increases gradually from 24 to 51.5 mm over the 0.17 to 3.07 g size range. This was attributed to the increased radii of curvature.     

Cerebral areas associated with motor control of speech in humans

Murphy, K., D. R. Corfield, A. Guz, G. R. Fink, R. J. S. Wise, J. Harrison, and L. Adams. Cerebral areas associated withmotor control of speech in humans. J. Appl.Physiol. 83(5): 1438-1447, 1997.We have definedareas in the brain activated during speaking, utilizing positronemission tomography. Six normal subjects continuously repeated thephrase "Buy Bobby a poppy" (requiring minimal languageprocessing) in four ways: A) spoken aloud, B) mouthed silently,C) without articulation, andD) thought silently. Statisticalcomparison of images from conditions Awith C andB withD highlighted areas associated witharticulation alone, because control of breathing for speech wascontrolled for; we found bilateral activations in sensorimotor cortexand cerebellum with right-sided activation in the thalamus/caudate nucleus. Contrasting images from conditionsA with B andC with D highlighted areas associated withthe control of breathing for speech, vocalization, and hearing, becausearticulation was controlled for; we found bilateral activations insensorimotor and motor cortex, close to but distinct from theactivations in the preceding contrast, together with activations inthalamus, cerebellum, and supplementary motor area. In neithersubtraction was there activation in Broca's area. These resultsemphasize the bilaterality of the cerebral control of "speaking"without language processing.

     

Mapping of alpha-melanocyte-stimulating hormone-like immunoreactivity in the cat brainstem

The distribution of alpha-melanocyte-stimulating hormone-like immunoreactive structures was studied in the brainstem of the cat using an indirect immunoperoxidase technique. Immunoreactivity was observed in several brainstem nuclei of the cat in which no immunoreactivity had been previously reported. Immunoreactive fibres were observed in the following; the inferior central nucleus; the pontine gray nuclei; the K?lliker-Fuse nucleus; the motor trigeminal nucleus, the anteroventral cochlear nucleus; the abducens nucleus; the retrofacial nucleus; the superior, lateral, inferior, and medial vestibular nuclei; the lateral nucleus of the superior olive; the external cuneate nucleus; the nucleus of the trapezoid body; the postpyramidal nucleus of the raphe; the medial accessory inferior olive; the dorsal accessory nucleus of the inferior olive; the nucleus ambiguus; the principal nucleus of the inferior olive; the preolivary nucleus; the nucleus ruber; the substantia nigra; and in the area postrema. Our results point to a more widespread distribution of alpha-melanocyte-stimulating hormone-like immunoreactive structures in the cat brainstem than that reported in previous studies carried out in the same region of the cat, rat and humans.