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4. Working Together: Building Effective Software Engineering Team

Author

Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Hogan, James, Thomas, Richard, Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Hogan, James, and Thomas, Richard

Abstract

It is by now an obvious observation that much of the world depends on information technology. Our infrastructure relies on IT: our buildings, finance systems, roads, airplanes, cars, televisions, washing ma-chines and bread makers; as does much of what we do: our banking, learning and communicating. Almost everyone today uses information technology, but few know how it works, and very few indeed under-stand the mysteries of how to build new systems. This imbalance be-tween ‘users’ and ‘knowers’ grows worse every year. With the ‘dot com collapse’, the number of students studying computers, and information technology more generally, has been shrinking steadily. In the long run, this trend is not likely to be a good thing, either in Australia or else-where. What can we do about this? IT courses worldwide report falling enrollments and high attrition. The glamor of computing – seemingly effortless graphics and animations, and the management of massive computations and data sets – is at odds with the reality of how difficult it can be to coax computers into exhibiting these advanced capabilities; and many students find the transition from the dream to reality too difficult to master. One possibility is to reconceptualize both what and how we teach, making IT more attractive to students without sacrificing the rigor and depth needed to produce graduates capable of life-long learning against the backdrop of rapidly evolving technologies. The Faculty of Information Technology at QUT has long sought to develop curricula and pedagogies that make this possible. The results of this search show in innovative curricula, real-world engagement, and a dominant position in our local market for IT education. QUT’s strategic plan, the ‘QUT Blueprint’*, exhorts the University to be bold, experiment, and engage with the real world in order to ensure we remain relevant and attuned to the needs of both our graduates and the industries that will employ them. The contents of this book report

Published
2006

5. Beyond the Components: Use of a Virtual Project Environment to Encourage Deeper Understanding

Author

Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Jewels, Tony, Jones, Wendy, Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Jewels, Tony, and Jones, Wendy

Abstract

In the design and delivery of a new IT project management (ITPM) unit, a pedagogy was adopted to provide postgraduate and final year undergraduate students with what was believed to offer the most appropriate skills and relevant knowledge to take them into the workforce. Providing a rich, descriptive, project environment for students in the form of a single case study, it was expected that students would become deeply embedded in the case and subsequently gain a greater understanding of the theoretical constructs covered in the unit. Additionally, it was hoped that 'deep immersion' into the case would provide students with the opportunity to understand the totality of the system and the interrelationships between the individual constructs. The integration of a single case study into the unit curriculum as a sort of 'virtual environment' provided challenges for both students and teaching staff alike and required ongoing evaluation and modifications to ensure that the pedagogy was appropriate for its purpose.

Published
2006

7. MBTI Distributions for First Year IT Students

Author

Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Stewart, Glenn, Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, and Stewart, Glenn

Abstract

It is by now an obvious observation that much of the world depends on information technology. Our infrastructure relies on IT: our buildings, finance systems, roads, airplanes, cars, televisions, washing ma-chines and bread makers; as does much of what we do: our banking, learning and communicating. Almost everyone today uses information technology, but few know how it works, and very few indeed under-stand the mysteries of how to build new systems. This imbalance be-tween ‘users’ and ‘knowers’ grows worse every year. With the ‘dot com collapse’, the number of students studying computers, and information technology more generally, has been shrinking steadily. In the long run, this trend is not likely to be a good thing, either in Australia or else-where. What can we do about this? IT courses worldwide report falling enrollments and high attrition. The glamor of computing – seemingly effortless graphics and animations, and the management of massive computations and data sets – is at odds with the reality of how difficult it can be to coax computers into exhibiting these advanced capabilities; and many students find the transition from the dream to reality too difficult to master. One possibility is to reconceptualize both what and how we teach, making IT more attractive to students without sacrificing the rigor and depth needed to produce graduates capable of life-long learning against the backdrop of rapidly evolving technologies. The Faculty of Information Technology at QUT has long sought to develop curricula and pedagogies that make this possible. The results of this search show in innovative curricula, real-world engagement, and a dominant position in our local market for IT education. QUT’s strategic plan, the ‘QUT Blueprint’*, exhorts the University to be bold, experiment, and engage with the real world in order to ensure we remain relevant and attuned to the needs of both our graduates and the industries that will employ them. The contents of this book report

Published
2006

10. Planning Explanations

Author

Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Reye, Jim, Wheeldon, Alan, Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Reye, Jim, and Wheeldon, Alan

Published
2006

11. Panning for Gold: Understanding Students' Information Searching Experiences

Author

Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Edwards, Sylvia, Bruce, Christine, Bruce, C, Mohay, G, Smith, G, Stoodley, I, Tweedale, R, Edwards, Sylvia, and Bruce, Christine

Abstract

When was the last time you observed someone searching the Internet or library databases and wondered, "Why on earth did they do it that way?" Searchers are prepared to sit for long periods trying to find the elusive and even rare item they require, yet spend little time learning how to search more effectively. Reflections of this nature led to the research reported in this paper. Observing students over a period of a few years, all studying within one unit in the Faculty of Information Technology (FIT), Queensland University of Technology (QUT), it became clear that efforts to understand what students were experiencing while web-based information searching would be valuable for both the students and ongoing curriculum design. This paper reports on research intended to discover both the student experiences and the likely ways to encourage students to pan for gold rather than junk when they search. The research was undertaken using a phenomenographic approach. The paper will outline the background to the study, explain the research method and objectives, and present findings. Both teaching and learning strategies and curriculum design have been strongly influenced by this project

Published
2006

13. Short-term plasticity in adult somatosensory cortex

Author

Calford, M B, Clarey, J C, Tweedale, R, Calford, M B, Clarey, J C, and Tweedale, R

Abstract

The primary sensory fields in cortex encode topographical representations of their peripheral epithelium (visual: retina; somatosensory: body surface; auditory: cochlear place or frequency) in which responsive neurons at a given locus or throughout a column have similar receptive fields, These representations provide useful model systems for the study of functional neuronal plasticity since they present an inbuilt scale upon which any changes can be measured. In the developing mammal, these representations have been shown to be capable of a remarkable degree of plasticity by virtue of the reorganization of the basic topography which follows from a changed peripheral input (Kelahan et aI., 1981; Spinelli and Jensen, 1979; Waite. 1984; Wall and Cusick, 1986) or from manipulation of central pathways (Roe et al 1990), Plasticity has also been demonstrated in the sensory cortex of adults where the removal of a restricted region of primary afferents can lead to the affected area of cortex gaining sensitivity to other regions (visual: Gilbert and Wiesel, 1992; Kaas et al 1990; Schmid et al 1995; 1996; auditory: Rajan et al 1993; Robertson and Irvine, 1989; somatosensory: see below). However, such changes in the organization of adult cortex must be considered fundamentally different in nature from those in neonates where there is a critical period for plasticity (Hubel and Wiesel, 1970; Wall, 1988). In the developing nervous system there are bases for mutability of the pattern of projections through disruption of the processes of initial connections, trimming of exuberant projections (e,g, Wall and Cusick, 1986) or alterations to the normal patterns of segregation of inputs (e.g. LeVay et al 1981). Such mechanisms of plasticity are not available in the adult brain where the connections are considered to be stable - although it does appear that some deprivation conditions may extend the developmental critical period (Daw et al 1992; Moore, 1993; Smith et al 1978), Neverthele

Published
1998

14. Acute changes in cutaneous receptive-fields in primary somatosensory cortex after digit denervation in adult flying fox

Author

Calford, M B, Tweedale, R, Calford, M B, and Tweedale, R

Abstract

1. Acute effects of permanent and temporary denervation of the flying fox thumb were examined to test the hypothesis that a large area of skin around the cutaneous receptive field of multiunits (MRF) at a locus in primary somatosensory cortex (SI) supplies viable inputs which can be rapidly unmasked by interruption of the dominant input from the area of the MRF. 2. The immediate effect of amputation of the thumb at loci where the original receptive field was entirely removed was to produce large MRFs on adjacent body areas (wrist, forearm, prowing, and finger membranes). Greatly expanded MRFs were also produced when amputation removed only part of the original MRF at a cortical locus. 3. The probable source of input to account for the new receptive fields is the extensive arborization of ascending projections within the somatosensory pathway, which supply a cortical locus with a potential input from a far larger area than is represented in its normal receptive field. The rapidity with which new or expanded fields are seen following denervation indicates that the normally unexpressed inputs around a receptive field are not only potential inputs but are inherently viable. Hence the most likely explanation for the results of this study is that the effect of the denervation is to disrupt an inhibitory influence that normally has the role of shaping the receptive field. 4. Temporary anesthesia of all or part of a MRF produced similar initial effects to amputation. When responsiveness returned to the locally anesthetized area (after 10-30 min), an expanded MRF persisted for a short time after which the boundaries of the MRF shrank. This rapid reversal suggests that a mechanistic rather than a plastic change is the basis for the acute effect of a small denervation on SI.

Published
1991

15. Immediate expansion of receptive fields of neurons in area 3b of macaque monkeys after digit denervation

Author

Calford, M B, Tweedale, R, Calford, M B, and Tweedale, R

Abstract

The short-term effect of total or partial single-digit denervation on receptive fields (Rds) of neurons in somatosensory cortex (area 3b) was examined in five macaque monkeys. In two animals, after denervation by amputation, it was found that electrode positions that initially recorded neurons with Rds on the amputated digit had new Rds extending from the wound. Often the new fields were on adjacent digits. Neurons with initial Rds that were partially amputated, or in some cases close to but not on the amputated digit, showed considerable expansion of the remaining RF. In three monkeys local anesthesia was used to provide a temporary denervation. In these experiments electrodes were placed in equivalent positions in both cortices. The effect on cortex contralateral to the denervation was similar to that seen with amputation. However, after esthesia returned to the digit, the expanded Rds contracted. In cortex ipsilateral to the denervation, Rds were on the opposite unaffected hand. These also rapidly expanded and then contracted, with the same time course as their counterparts in cortex contralateral to the denervation. Because of the rapidity of the expansion and its temporary nature with short-term denervation, the basis of the effect is probably an unmasking of existing but normally unexpressed connections, which are normally inhibited by the intact output from the denervated area. The wide arborization fields of thalamocortical afferents provide a potential source for the unmasked sensitivity. A mechanism for the inhibition that normally suppresses the expression of large Rds is not readily apparent. However, work in other species suggests that peripheral C fibers provide the primary source of input to central inhibitory circuits.

Published
1991

20. Effect of epidermal growth factor on reproductive function of ewes

Author

Shaw, G., Jorgensen, G. I., Tweedale, R., Tennison, M., and Waters, M. J.

Abstract

Adult Merino ewes were infused via the jugular vein with either saline (n= 5) or epidermal growth factor (EGF) (4·2 μg/kg per h, n= 6) for 24 h in either the luteal phase or the follicular phase of the oestrous cycle and reproductive function was examined.Infusion of EGF during the luteal phase caused no detectable change in plasma progesterone or prolactin concentrations over a 7-day period compared with the controls.Infusion of EGF during the follicular phase suppressed the oestrous rise in plasma oestradiol. Luteinizing hormone pulse amplitude was increased and pulse frequency was decreased by the end of the infusion. All control ewes had a pro-oestrous LH surge and mated, but the LH surge and oestrus were prevented by EGF infusion. Nevertheless, plasma progesterone levels rose subsequently in the EGF-infused ewes in parallel with the control ewes, suggesting that the preovulatory follicle had luteinized. Both LH and FSH rose over the 7 days after EGF infusion to levels similar to those in ovariectomized ewes.Thus EGF appears to inhibit follicular oestradiol production, although it does not affect luteal progesterone production or follicular luteinization. We suggest that the alteration in gonadotrophin secretion patterns results from a disturbance of feedback mechanisms between the ovary and the hypothalamopituitary axis, although a direct effect in the brain or the pituitary gland cannot yet be excluded.J. Endocr.(1985) 107,429–436

Published
1985
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21. Interhemispheric modulation of somatosensory receptive fields: evidence for plasticity in primary somatosensory cortex.

Author

Clarey, J C, Tweedale, R, and Calford, M B

Abstract

Extracellular recordings were made from single and multiple neurons in primary somatosensory cortex (area 3b) of macaque monkeys and flying foxes. When a small region of area 3b (or adjacent area 1) in the opposite hemisphere was cooled, thereby blocking activity that is normally transferred via the corpus callosum, larger receptive fields (RFs) were immediately unmasked for most neurons. RF expansion presumably reflects the expression of afferent inputs that are normally inhibited, suggesting that callosal inputs provide a source of tonic inhibition that contributes to the shaping of neuronal RFs. Quantitative analyses of single neuron responses revealed other effects that were consistent with a release from inhibition, such as increases in response magnitude to stimulation of points within the original RF and decreases in response latency. An unexpected finding was the reversal of these unmasking effects with extended periods of cooling: RFs returned to their original dimensions and within-field response magnitude decreased. In contrast to the initial effects, this reversal of disinhibition cannot be readily explained by an unmasking of previously unexpressed inputs. Any explanation for the reversal requires an increase in the efficacy of interneuron-mediated inhibition, and presumably occurs in response to ongoing, altered patterns of activity.

Published
1996
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22. Effects of oxytocin on the bovine corpus luteum of early pregnancy

Author

Tan, G. J. S., Tweedale, R., and Biggs, J. S. G.

Abstract

Summary.Oxytocin, at concentrations of 4 and 40 mi.u./ml, significantly enhanced progesterone production by dispersed bovine luteal cells (0·5–4 months of gestation) after incubation for 3 h. The luteotrophic effect of 4 mi.u. oxytocin/ml was comparable to that of 10 i.u. hCG/ml. Higher oxytocin concentration (800 mi.u./ml) markedly inhibited the response of the luteal cells to hCG and may be inhibitory to basal progesterone production. These data provide evidence for an effect of oxytocin on the bovine corpus luteum of early pregnancy.

Published
1982
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23. Oxytocin may play a role in the control of the human corpus luteum

Author

Tan, G. J. S., Tweedale, R., and Biggs, J. S. G.

Abstract

The effects of oxytocin on dispersed luteal cells from human corpora lutea of the menstrual cycle were studied. Oxytocin at a concentration of 4 mi.u./ml produced a slight increase in basal progesterone production. However, higher oxytocin concentrations (400 and 800 mi.u./ml) markedly inhibited both basal and human chorionic gonadotrophin-induced progesterone production. These data provide evidence for an effect of oxytocin on the human corpus luteum. In view of the inhibitory action of oxytocin, increased secretion of this hormone may be important in the demise of the corpus luteum at the end of the menstrual cycle.

Published
1982
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24. Interhemispheric transfer of plasticity in the cerebral cortex.

Author

Calford, M.B. and Tweedale, R.

Subjects
*BRAIN research
Abstract

Presents physiological data that shows homotopic regions of primary somatosensory cortex in the brain are linked so that plasticity induced in one hemisphere is immediately mirrored in the other. Lack of neuron responsiveness; Conclusions.

Published
1990
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28. Connections of the Dorsomedial Visual Area: Pathways for Early Integration of Dorsal and Ventral Streams in Extrastriate Cortex

Author

James A. Bourne, Rohan Tweedale, Susan Palmer, Hsin-Hao Yu, Michela Gamberini, David H. Reser, Kathleen J. Burman, Claudio Galletti, Marcello G. P. Rosa, Rosa M.G., Palmer S.M., Gamberini M., Burman K.J., Yu H.H., Reser D.H., Bourne J.A., Tweedale R., and Galletti C.

Subjects
Time Factors, genetic structures, Visual space, media_common.quotation_subject, Motion Perception, Posterior parietal cortex, Extrastriate cortex, Perception, biology.animal, medicine, Animals, Visual Pathways, Vision for perception and vision for action, Binocular neurons, Visual Cortex, media_common, Cerebral Cortex, Brain Mapping, biology, General Neuroscience, Marmoset, Callithrix, Articles, medicine.anatomical_structure, parietal cortex, Peripheral vision, Psychology, Neuroscience
Abstract

The dorsomedial area (DM), a subdivision of extrastriate cortex characterized by heavy myelination and relative emphasis on peripheral vision, remains the least understood of the main targets of striate cortex (V1) projections in primates. Here we placed retrograde tracer injections encompassing the full extent of this area in marmoset monkeys, and performed quantitative analyses of the numerical strengths and laminar patterns of its afferent connections. We found that feedforward projections from V1 and from the second visual area (V2) account for over half of the inputs to DM, and that the vast majority of the remaining connections come from other topographically organized visual cortices. Extrastriate projections to DM originate in approximately equal proportions from adjacent medial occipitoparietal areas, from the superior temporal motion-sensitive complex centered on the middle temporal area (MT), and from ventral stream-associated areas. Feedback from the posterior parietal cortex and other association areas accounts for

Published
2009
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29. Connections of the dorsomedial visual area: pathways for early integration of dorsal and ventral streams in extrastriate cortex.

Author

Rosa MG, Palmer SM, Gamberini M, Burman KJ, Yu HH, Reser DH, Bourne JA, Tweedale R, and Galletti C

Subjects
Animals, Brain Mapping methods, Callithrix, Cerebral Cortex physiology, Motion Perception physiology, Time Factors, Visual Cortex physiology, Visual Pathways physiology
Abstract

The dorsomedial area (DM), a subdivision of extrastriate cortex characterized by heavy myelination and relative emphasis on peripheral vision, remains the least understood of the main targets of striate cortex (V1) projections in primates. Here we placed retrograde tracer injections encompassing the full extent of this area in marmoset monkeys, and performed quantitative analyses of the numerical strengths and laminar patterns of its afferent connections. We found that feedforward projections from V1 and from the second visual area (V2) account for over half of the inputs to DM, and that the vast majority of the remaining connections come from other topographically organized visual cortices. Extrastriate projections to DM originate in approximately equal proportions from adjacent medial occipitoparietal areas, from the superior temporal motion-sensitive complex centered on the middle temporal area (MT), and from ventral stream-associated areas. Feedback from the posterior parietal cortex and other association areas accounts for <10% of the connections. These results do not support the hypothesis that DM is specifically associated with a medial subcircuit of the dorsal stream, important for visuomotor integration. Instead, they suggest an early-stage visual-processing node capable of contributing across cortical streams, much as V1 and V2 do. Thus, although DM may be important for providing visual inputs for guided body movements (which often depend on information contained in peripheral vision), this area is also likely to participate in other functions that require integration across wide expanses of visual space, such as perception of self-motion and contour completion.

Published
2009
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30. Brain maps, great and small: lessons from comparative studies of primate visual cortical organization.

Author

Rosa MG and Tweedale R

Subjects
Anatomy, Comparative, Animals, Physiology, Comparative, Primates anatomy & histology, Visual Cortex embryology, Biological Evolution, Brain Mapping, Models, Biological, Primates physiology, Visual Cortex anatomy & histology, Visual Cortex physiology, Visual Perception physiology
Abstract

In this paper, we review evidence from comparative studies of primate cortical organization, highlighting recent findings and hypotheses that may help us to understand the rules governing evolutionary changes of the cortical map and the process of formation of areas during development. We argue that clear unequivocal views of cortical areas and their homologies are more likely to emerge for "core" fields, including the primary sensory areas, which are specified early in development by precise molecular identification steps. In primates, the middle temporal area is probably one of these primordial cortical fields. Areas that form at progressively later stages of development correspond to progressively more recent evolutionary events, their development being less firmly anchored in molecular specification. The certainty with which areal boundaries can be delimited, and likely homologies can be assigned, becomes increasingly blurred in parallel with this evolutionary/developmental sequence. For example, while current concepts for the definition of cortical areas have been vindicated in allowing a clarification of the organization of the New World monkey "third tier" visual cortex (the third and dorsomedial areas, V3 and DM), our analyses suggest that more flexible mapping criteria may be needed to unravel the organization of higher-order visual association and polysensory areas.

Published
2005
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31. Resolving the organization of the New World monkey third visual complex: the dorsal extrastriate cortex of the marmoset (Callithrix jacchus).

Author

Rosa MG, Palmer SM, Gamberini M, Tweedale R, Piñon MC, and Bourne JA

Subjects
Action Potentials physiology, Animals, Axons physiology, Brain Mapping, Callithrix physiology, Fluorescent Dyes, Photic Stimulation, Visual Cortex physiology, Visual Fields physiology, Visual Pathways physiology, Visual Perception physiology, Axons ultrastructure, Callithrix anatomy & histology, Visual Cortex anatomy & histology, Visual Pathways anatomy & histology
Abstract

We tested current hypotheses on the functional organization of the third visual complex, a particularly controversial region of the primate extrastriate cortex. In anatomical experiments, injections of retrograde tracers were placed in the dorsal cortex immediately rostral to the second visual area (V2) of New World monkeys (Callithrix jacchus), revealing the topography of interconnections between the "third tier" cortex and the primary visual area (V1). The data indicate the presence of a dorsomedial area (DM), which represents the entire upper and lower quadrants of the visual field, and which receives strong, topographically organized projections from the superficial layers of V1. The visuotopic organization and boundaries of DM were confirmed by electrophysiological recordings in the same animals and by architectural characteristics which were distinct from those found in ventral extrastriate cortex rostral to V2. There was no electrophysiological or histological evidence for a transitional area between V2 and DM. In particular, the central representation of the upper quadrant in DM was directly adjacent to the representation of the horizontal meridian that marks the rostral border of V2. The present results argue in favor of the hypothesis that the third visual complex in New World monkeys contains different areas in its dorsal and ventral components: area DM, near the dorsal midline, and a homolog of area 19 of other mammals, located more lateral and ventrally. The characteristics of DM suggest that it may correspond to visual area 6 (V6) of Old World monkeys.

Published
2005
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32. Physiological responses of New World monkey V1 neurons to stimuli defined by coherent motion.

Author

Bourne JA, Tweedale R, and Rosa MG

Subjects
Animals, Callithrix, Visual Cortex anatomy & histology, Visual Cortex physiology, Motion Perception physiology, Neurons physiology, Photic Stimulation methods
Abstract

We studied the responses of neurons in area V1 of marmosets to visual stimuli that moved against dynamic textured backgrounds. The stimuli were defined either by a first-order cue ('solid' bars, which were either darker or lighter than the background) or by a second-order cue ('camouflaged' bars, defined only by coherent motion). Forty-two per cent of the neurons demonstrated a similar selectivity for the direction of motion of the solid and camouflaged bars, thereby characterizing a population of cue-invariant (CI) cells. The other cells either showed different selectivity to the movement of solid and camouflaged bars (non-cue-invariant, or NCI cells), or responded equally well to movement in all directions. CI neurons, which were rare in layer 4, tended to have larger receptive fields and to be more strongly direction selective than NCI cells. Although V1 neurons tended to show maximal responses to camouflaged bars that were longer than the 'optimal' solid bars, many CI neurons preferred first- and second-order stimuli of similar lengths. Finally, the activity evoked by the camouflaged bars was delayed in relation to that evoked by solid bars. These results demonstrate that motion CI responses are relatively common in primate V1, especially among a population of strongly direction-selective neurons. They also indicate that this response property may depend on feedback from extrastriate areas, or on complex intrinsic interactions within V1.

Published
2002
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33. The dorsomedial visual areas in New World and Old World monkeys: homology and function.

Author

Rosa MG and Tweedale R

Subjects
Animals, Cebidae physiology, Cercopithecidae physiology, Psychomotor Performance physiology, Visual Cortex physiology
Abstract

The extrastriate cortex near the dorsal midline has been described as part of an 'express' pathway that provides visual input to the premotor cortex. This pathway is considered important for the integration of sensory information about the visual field periphery and the skeletomotor system, especially in relation to the control of arm movements. However, a better understanding of the functional contributions of different parts of this complex has been hampered by the lack of data on the extent and boundaries of its constituent visual areas. Recent studies in macaques have provided the first detailed view of the topographical organization of this region in Old World monkeys. Despite differences in nomenclature, a comparison of the visuotopic organization, myeloarchitecture and connections of the relevant visual areas with those previously studied in New World monkeys reveals a remarkable degree of similarity and helps to clarify the subdivision of function between different areas of the dorsomedial complex. A caudal visual area, named DM or V6, appears to be important for the detection of coherent patterns of movement across wide regions of the visual field, such as those induced during self-motion. A rostral area, named M or V6A, is more directly involved with visuomotor integration. This area receives projections both from DM/V6 and from a separate motion analysis channel, centred on the middle temporal visual area (or V5), which detects the movement of objects in extrapersonal space. These results support the suggestion, made earlier on the basis of more fragmentary evidence, that the areas rostral to the second visual area in dorsal cortex are homologous in all simian primates. Moreover, they emphasize the importance of determining the anatomical organization of the cortex as a prerequisite for elucidating the function of different cortical areas.

Published
2001
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34. Visual responses of neurons in the middle temporal area of new world monkeys after lesions of striate cortex.

Author

Rosa MG, Tweedale R, and Elston GN

Subjects
Animals, Blindness, Cortical, Brain Mapping, Callithrix, Cerebral Decortication, Photic Stimulation methods, Scotoma, Visual Cortex surgery, Visual Pathways physiology, Neurons physiology, Temporal Lobe physiology, Visual Cortex physiology, Visual Fields physiology
Abstract

In primates, lesions of striate cortex (V1) result in scotomas in which only rudimentary visual abilities remain. These aspects of vision that survive V1 lesions have been attributed to direct thalamic pathways to extrastriate areas, including the middle temporal area (MT). However, studies in New World monkeys and humans have questioned this interpretation, suggesting that remnants of V1 are responsible for both the activation of MT and residual vision. We studied the visual responses of neurons in area MT in New World marmoset monkeys in the weeks after lesions of V1. The extent of the scotoma in each case was estimated by mapping the receptive fields of cells located near the lesion border and by histological reconstruction. Two response types were observed among the cells located in the part of MT that corresponds, in visuotopic coordinates, to the lesioned part of V1. Many neurons (62%) had receptive fields that were displaced relative to their expected location, so that they represented the visual field immediately surrounding the scotoma. This may be a consequence of a process analogous to the reorganization of the V1 map after retinal lesions. However, another 20% of the cells had receptive fields centered inside the scotoma. Most of these neurons were strongly direction-selective, similar to normal MT cells. These results show that MT cells differ in their responses to lesioning of V1 and that only a subpopulation of MT neurons can be reasonably linked to residual vision and blindsight.

Published
2000

35. Visual areas in lateral and ventral extrastriate cortices of the marmoset monkey.

Author

Rosa MG and Tweedale R

Subjects
Animals, Callithrix anatomy & histology, Male, Neural Pathways physiology, Visual Cortex anatomy & histology, Brain Mapping methods, Callithrix physiology, Visual Cortex physiology, Visual Fields physiology
Abstract

The representation of the visual field in visual areas of the dorsolateral, lateral, and ventral cortices was studied by means of extracellular recordings and fluorescent tracer injections in anaesthetised marmoset monkeys. Two areas, forming mirror-symmetrical representations of the contralateral visual field, were found rostral to the second visual area (V2). These were termed the ventrolateral posterior (VLP) and the ventrolateral anterior (VLA) areas. In both areas, the representation of the lower quadrant is located dorsally, between the foveal representation of V2 and the middle temporal crescent (MTc), whereas the representation of the upper quadrant is located ventrally, in the supratentorial cortex. A representation of the vertical meridian forms the common border of areas VLP and VLA, whereas the horizontal meridian is represented both at the caudal border of area VLP (with V2) and at the rostral border of area VLA (with multiple extrastriate areas). The foveal representations of areas VLP and VLA are continuous with that of V2, being located at the lateral edge of the hemisphere. The topographic and laminar patterns of projections from dorsolateral and ventral cortices to the primary (V1) and dorsomedial (DM) visual areas both support the present definition of the borders of areas VLP and VLA. These results argue against a separation between dorsolateral and ventral extrastriate areas and provide clues for the likely homologies between extrastriate areas of different species., (Copyright 2000 Wiley-Liss, Inc.)

Published
2000
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36. Cellular heterogeneity in cerebral cortex: a study of the morphology of pyramidal neurones in visual areas of the marmoset monkey.

Author

Elston GN, Tweedale R, and Rosa MG

Subjects
Animals, Cerebral Cortex anatomy & histology, Dendrites ultrastructure, Fluorescent Dyes, Image Processing, Computer-Assisted, Isoquinolines, Macaca anatomy & histology, Male, Temporal Lobe cytology, Visual Cortex anatomy & histology, Callithrix anatomy & histology, Cerebral Cortex cytology, Neurons cytology, Pyramidal Cells cytology, Visual Cortex cytology
Abstract

The morphological characteristics of the basal dendritic fields of layer III pyramidal neurones were determined in visual areas in the occipital, parietal, and temporal lobes of adult marmoset monkeys by means of intracellular iontophoretic injection of Lucifer yellow. Neurones in the primary visual area (V1) had the least extensive and least complex (as determined by Sholl analysis) dendritic trees, followed by those in the second visual area (V2). There was a progressive increase in size and complexity of dendritic trees with rostral progression from V1 and V2, through the "ventral stream," including the dorsolateral area (DL) and the caudal and rostral subdivisions of inferotemporal cortex (ITc and ITr, respectively). Neurones in areas of the dorsal stream, including the dorsomedial (DM), dorsoanterior (DA), middle temporal (MT), and posterior parietal (PP) areas, were similar in size and complexity but were larger and more complex than those in V1 and V2. Neurones in V1 had the lowest spine density, whereas neurones in V2, DM, DA, and PP had similar spine densities. Neurones in MT and inferotemporal cortex had relatively high spine densities, with those in ITr having the highest spine density of all neurones studied. Calculations based on the size, number of branches, and spine densities revealed that layer III pyramidal neurones in ITr have 7.4 times more spines on their basal dendritic fields than those in V1. The differences in the extent of, and the number of spines in, the basal dendritic fields of layer III pyramidal neurones in the different visual areas suggest differences in the ability of neurones to integrate excitatory and inhibitory inputs. The differences in neuronal morphology between visual areas, and the consistency in these differences across New World and Old World monkey species, suggest that they reflect fundamental organisational principles in primate visual cortical structure., (Copyright 1999 Wiley-Liss, Inc.)

Published
1999
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37. Cortical integration in the visual system of the macaque monkey: large-scale morphological differences in the pyramidal neurons in the occipital, parietal and temporal lobes.

Author

Elston GN, Tweedale R, and Rosa MG

Subjects
Animals, Dendrites ultrastructure, Macaca fascicularis, Male, Visual Cortex cytology, Occipital Lobe cytology, Parietal Lobe cytology, Pyramidal Cells ultrastructure, Temporal Lobe cytology
Abstract

Layer III pyramidal neurons were injected with Lucifer yellow in tangential cortical slices taken from the inferior temporal cortex (area TE) and the superior temporal polysensory (STP) area of the macaque monkey. Basal dendritic field areas of layer III pyramidal neurons in area STP are significantly larger, and their dendritic arborizations more complex, than those of cells in area TE. Moreover, the dendritic fields of layer III pyramidal neurons in both STP and TE are many times larger and more complex than those in areas forming 'lower' stages in cortical visual processing, such as the first (V1), second (V2), fourth (V4) and middle temporal (MT) visual areas. By combining data on spine density with those of Sholl analyses, we were able to estimate the average number of spines in the basal dendritic field of layer III pyramidal neurons in each area. These calculations revealed a 13-fold difference in the number of spines in the basal dendritic field between areas STP and V1 in animals of similar age. The large differences in complexity of the same kind of neuron in different visual areas go against arguments for isopotentiality of different cortical regions and provide a basis that allows pyramidal neurons in temporal areas TE and STP to integrate more inputs than neurons in more caudal visual areas.

Published
1999
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38. Supragranular pyramidal neurones in the medial posterior parietal cortex of the macaque monkey: morphological heterogeneity in subdivisions of area 7.

Author

Elston GN, Tweedale R, and Rosa MG

Subjects
Animals, Cell Size, Dendrites, Fluorescent Dyes, Isoquinolines, Macaca fascicularis, Male, Microinjections, Pyramidal Cells ultrastructure, Somatosensory Cortex cytology, Parietal Lobe cytology, Pyramidal Cells cytology, Visual Cortex cytology
Abstract

Pyramidal neurones were injected with Lucifer Yellow in cortical slices taken from layer III of the medial subdivision of cytoarchitectonic area 7 (7m) of the macaque monkey. Cross-sectional area, branching complexity and spine density of the basal dendritic fields were determined and compared with those of neurones in other areas of the dorsal processing stream. Layer III pyramidal neurones in area 7m have an average basal dendritic field area of 109.57 +/- 13.03 x 10(3) microm2, which is significantly greater than that obtained for neurones in the lateral intraparietal area (LIP) and area 7a. Moreover, Sholl analyses revealed that neurones in area 7m are significantly more complex in their branching patterns than those in LIP and area 7a. These results reinforce the view that, behind the apparent architectural uniformity of Brodmann's area 7, there is a significant diversity of neuronal structure and function.

Published
1999
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39. Interhemispheric connections of somatosensory cortex in the flying fox.

Author

Krubitzer L, Clarey JC, Tweedale R, and Calford MB

Subjects
Animals, Brain Mapping, Chiroptera physiology, Corpus Callosum physiology, Somatosensory Cortex physiology, Chiroptera anatomy & histology, Corpus Callosum anatomy & histology, Somatosensory Cortex anatomy & histology
Abstract

The interhemispheric connections of somatosensory cortex in the gray-headed flying fox (Pteropus poliocephalus) were examined. Injections of anatomical tracers were placed into five electrophysiologically identified somatosensory areas: the primary somatosensory area (SI or area 3b), the anterior parietal areas 3a and 1/2, and the lateral somatosensory areas SII (the secondary somatosensory area) and PV (pairetal ventral area). In two animals, the hemisphere opposite to that containing the injection sites was explored electrophysiologically to allow the details of the topography of interconnections to be assessed. Examination of the areal distribution of labeled cell bodies and/or axon terminals in cortex sectioned tangential to the pial surface revealed several consistent findings. First, the density of connections varied as a function of the body part representation injected. For example, the area 3b representation of the trunk and structures of the face are more densely interconnected than the representation of distal body parts (e.g., digit 1, D1). Second, callosal connections appear to be both matched and mismatched to the body part representations injected in the opposite hemisphere. For example, an injection of retrograde tracer into the trunk representation of area 3b revealed connections from the trunk representation in the opposite hemisphere, as well as from shoulder and forelimb/wing representations. Third, the same body part is differentially connected in different fields via the corpus callosum. For example, the D1 representation in area 3b in one hemisphere had no connections with the area 3b D1 representation in the opposite hemisphere, whereas the D1 representation in area 1/2 had relatively dense reciprocal connections with area 1/2 in the opposite hemisphere. Finally, there are callosal projections to fields other than the homotopic, contralateral field. For example, the D1 representation in area 1/2 projects to contralateral area 1/2, and also to area 3b and SII.

Published
1998

40. C-fibres provide a source of masking inhibition to primary somatosensory cortex.

Author

Calford MB and Tweedale R

Subjects
Afferent Pathways drug effects, Afferent Pathways physiology, Animals, Capsaicin administration & dosage, Cats, Denervation, Foxes, Nerve Fibers drug effects, Neuronal Plasticity drug effects, Neuronal Plasticity physiology, Neurons drug effects, Neurons physiology, Nerve Fibers physiology, Somatosensory Cortex physiology
Abstract

Capsaicin was applied to the exposed radial nerve of adult flying foxes (n = 5) and cats (n = 2) while recording in primary somatosensory cortex from a single neuron with a receptive field on digits 1 or 2. Within four minutes of application of capsaicin the borders of these receptive fields dramatically expanded. In a further four flying foxes it was shown, with subcutaneous delivery just proximal to the receptive fields, that capsaicin need affect only afferents from the region of a neuron's receptive field to induce expansion. Capsaicin applied directly to a nerve, or subcutaneously in high concentrations, is a selective neurotoxin that rapidly prevents the propagation of action potentials in most C-fibres. The result provides a partial explanation for experiments involving the specific and complete denervation of receptive fields of neurons in primary somatosensory cortex. Such denervation does not lead to unresponsiveness but to immediate sensitivity to stimulation of areas surrounding the original fields. Thus it appears that some subclass of capsaicin-sensitive C-fibres provides a primary source for the masking inhibition that normally limits the extent of the receptive fields of cortical neurons.

Published
1991
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41. The toxicity of metabolites of sodium valproate in cultured hepatocytes.

Author

Kingsley E, Gray P, Tolman KG, and Tweedale R

Subjects
Animals, Biotransformation, Cells, Cultured, L-Lactate Dehydrogenase analysis, Male, Rats, Rats, Inbred Strains, Valproic Acid metabolism, Liver drug effects, Valproic Acid toxicity
Abstract

Sodium valproate is hepatotoxic in both humans and rat hepatocytes. The toxicity is dose related and frequently associated with simultaneous ingestion of drugs which induce the drug metabolizing system. For these reasons, metabolites of sodium valproate were tested for toxicity using rat hepatocyte cultures. The sodium salts of three metabolites, 2-propylpent-4-enoate, 4-hydroxyvalproate, and perhaps 5-hydroxyvalproate, were toxic in this system. In addition, 2-propylpent-4-enoate was toxic in a dose-related fashion. All are omega and omega-1 oxidation products in the microsome-mediated pathway of valproate metabolism.

Published
1983
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42. Dedifferentiation of cultured thyroid cells by epidermal growth factor: some insights into the mechanism.

Author

Waters MJ, Tweedale RC, Whip TA, Shaw G, Manley SW, and Bourke JR

Subjects
Amiloride pharmacology, Animals, Biological Transport, Active drug effects, Cell Differentiation drug effects, Cell Division drug effects, Cyclic AMP pharmacology, Iodides metabolism, Kinetics, Receptors, Thyrotropin metabolism, Swine, Thyroid Gland metabolism, Thyrotropin metabolism, Thyrotropin pharmacology, Epidermal Growth Factor pharmacology, Thyroid Gland cytology
Abstract

Epidermal growth factor (EGF) has been shown to enhance both the proliferation and dedifferentiation of thyroid cells in culture, leading to a maintained dedifferentiated state, even in the presence of thyrotropin (TSH). Since this maintained loss of differentiated function is not seen with other mitogens, it may relate to a regulatory role for EGF in thyroid function. Therefore, we have examined the loci affected by the dedifferentiative actions of EGF using porcine thyroid cells in culture. EGF (10 ng/ml) induces a loss of thyrotropin (TSH) receptors with a time course identical to the loss in ability to transport iodide. This could account for the difference in extent of iodide uptake and morphological dedifferentiation seen between TSH- and cAMP-supported cells, although the fact that cAMP-supported cells also dedifferentiate implies a lesion distal to the cyclase. Reciprocal plot analysis of iodide uptake in control and EGF-treated cells shows that EGF increases the Km for iodide transport, corresponding to a decreased affinity of iodide pump sites for iodide. These effects on iodide pump affinity and TSH receptor number may result from reversal of thyroid cell polarity in monolayer culture, or they may be the result of more specific actions of EGF at these loci. It has been possible to discriminate between the proliferative and dedifferentiating actions of EGF using amiloride, a non-specific inhibitor of the Na+/H+ antiporter. An optimum concentration of amiloride (0.1 mM) was able to block EGF-stimulated incorporation of [3H]thymidine into DNA without preventing the blockade of iodide uptake, which implies that dedifferentiation is not a consequence of proliferation.(ABSTRACT TRUNCATED AT 250 WORDS)

Published
1987
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43. Immediate and chronic changes in responses of somatosensory cortex in adult flying-fox after digit amputation.

Author

Calford MB and Tweedale R

Subjects
Amputation, Surgical, Animals, Chiroptera anatomy & histology, Evoked Potentials, Somatosensory, Somatosensory Cortex pathology, Chiroptera physiology, Somatosensory Cortex physiology, Wings, Animal physiology
Abstract

The somatosensory cortex of adult mammals has been shown to have a capacity to reorganize when inputs are removed by cutting afferent nerves or amputating a part of the body. The area of cortex that would normally respond to stimulation of the missing input can become responsive to inputs from other parts of the body surface. Although a few animals have been studied with repeat recording, no attempt has been made to follow the time-course of changes at cortical loci and the immediate effects of a small amputation have not been reported. We have followed the changes in response in the primary somatosensory cortex in the flying-fox following amputation of the single exposed digit on the forelimb. Immediately after amputation, neurons in the area of cortex receiving inputs from the missing digit were not silent but responded to stimulation of adjoining regions of the digit, hand, arm and wing. In the week following amputation, the enlarged receptive fields shrank until they covered only the skin around the amputation wound. The immediate response is interpreted as a removal of inhibition and the subsequent shrinking of the field may be due to re-establishment of the inhibitory balance in the affected cortex and its inputs.

Published
1988
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