Assessing for cognitive impairment in people with an acquired brain injury : validation of a brief neuropsychological assessment battery

Attwood, Jennifer

January 2013

Cognitive complaints are common following an acquired brain injury and require careful assessment in order to guide treatment and care. There is a need for brief, comprehensive and psychometrically valid tests of cognitive function that can be used in neuro-rehabilitation services by a range of health professionals. The Short Parallel Assessments of Neuropsychological Status (SPANS) was purpose-designed to meet this need. The current study assessed the reliability, discriminative validity and factor structure of the SPANS. Participants were 61 people with an acquired brain injury, 35 people with a long-term neurological condition, and 122 healthy controls. Cronbach’s alphas were adequate to excellent for the clinical groups though poor for the healthy controls due to limited variance in the scores. Receiver operating characteristic curves showed that SPANS indices were significantly able to discriminate between people with a neurological condition and healthy controls as well as between left and right hemisphere damage. Exploratory factor analysis suggested the retention of 25 subtests representing three factors that largely followed the purported structure of the test: Memory and Learning, Language, and Visual-motor Performance. Limitations of the study, clinical/theoretical implications and research directions are considered. It is concluded that the SPANS is a reliable and valid tool for the assessment of cognitive function in people with an acquired brain injury, though further validation studies are required.

150

The Role of the Monkey Amygdala in the Autonomic Expression of Emotion

Spitler, Kevin M.

January 2007

The skin conductance response is involved in the preparation for and response to stimuli with emotional significance. The neural mechanisms responsible for the generation of the skin conductance response are not well understood despite the common use of this signal as an index of emotional response. Data from anatomical, lesion, and neuroimaging studies in humans suggest that the amygdala, a component of the brain circuit for emotion, plays a critical role in the generation of the skin conductance response. Here we employ a novel combination of existing techniques to understand the stimuli that elicit skin conductance responses in the monkey and the neural mechanisms in the amygdala that participate in its generation. We recorded skin conductance responses in monkeys trained to perform a passive image viewing task. This paradigm is a staple of human emotion research but to date has not been adapted to the monkey. In addition, skin conductance responses to these stimuli were recorded in conjunction with single unit responses from the amygdala. This study addresses the relationship between the activity of single neurons recorded from identified nuclei of the monkey amygdala and autonomic responses. Neurons in multiple nuclei of the amygdala showed reliable changes in neuronal discharge prior to the skin conductance response. These neurons were primarily in the dorsal nuclei of the amygdala, which confirms predictions made from anatomical and neuroimaging data. It is suggested that these changes in neuronal discharge may correspond to the generation of this autonomic component of the expression of emotion.

Emotion

Amygdala

Monkey

Neurophysiology

Skin Conductance Response

Galvanic Skin Response

The Control of temporally Urgent Movements

Lakhani, Bimal

10 January 2014

The ability to respond rapidly with spatial precision is required in a number of facets of everyday life, whether catching a falling object, reacting to other drivers on a busy freeway or recovering one’s balance following an unexpected perturbation. The sophisticated central nervous system (CNS) control of these reactions is often overlooked until the speed of such reactions becomes delayed, either due to ageing or brain injury, wherein the individual becomes at risk of injury. Surprisingly, little is known regarding the control of these ‘temporally urgent’ movements. Therefore, the primary objectives of this dissertation were to develop an understanding of the control of these movements by exploring the factors that may be involved in the generation of temporally urgent movements in the healthy CNS, locating the areas within the CNS that such modulation occurs and identifying the relative weighted importance of those modulators based on the initial conditions of stimulus delivery. Specific characteristics of stimulus properties, such as intensity and modality were particularly influential in the latency of motor reactions and physiological electrodermal skin responses fluctuated in accordance with input stimulus parameters. Importantly, outcomes from this dissertation identified that rapid reactions likely utilize a CNS network that includes higher cortical regions such as somatosensory cortex and primary motor cortex, which may be modulated by physiological arousal, rather than the solitary involvement of subcortical structures. The findings from this dissertation have important implications for individuals with disordered speed of processing and indicate the potential modifiability of factors that influence reaction time.

Reaction Time

Postural Control

Rehabilitation

Neurophysiology

0317

0382

0719

The Control of temporally Urgent Movements

Lakhani, Bimal

10 January 2014

The ability to respond rapidly with spatial precision is required in a number of facets of everyday life, whether catching a falling object, reacting to other drivers on a busy freeway or recovering one’s balance following an unexpected perturbation. The sophisticated central nervous system (CNS) control of these reactions is often overlooked until the speed of such reactions becomes delayed, either due to ageing or brain injury, wherein the individual becomes at risk of injury. Surprisingly, little is known regarding the control of these ‘temporally urgent’ movements. Therefore, the primary objectives of this dissertation were to develop an understanding of the control of these movements by exploring the factors that may be involved in the generation of temporally urgent movements in the healthy CNS, locating the areas within the CNS that such modulation occurs and identifying the relative weighted importance of those modulators based on the initial conditions of stimulus delivery. Specific characteristics of stimulus properties, such as intensity and modality were particularly influential in the latency of motor reactions and physiological electrodermal skin responses fluctuated in accordance with input stimulus parameters. Importantly, outcomes from this dissertation identified that rapid reactions likely utilize a CNS network that includes higher cortical regions such as somatosensory cortex and primary motor cortex, which may be modulated by physiological arousal, rather than the solitary involvement of subcortical structures. The findings from this dissertation have important implications for individuals with disordered speed of processing and indicate the potential modifiability of factors that influence reaction time.

Reaction Time

Postural Control

Rehabilitation

Neurophysiology

0317

0382

0719

Functional and Neurophysiological Correlates of Corticospinal Function in Human Aging

Davidson, Travis

06 September 2011

Transcranial magnetic stimulation (TMS) is a non-invasive technique that can be used to assess the integrity neuronal circuits in the motor cortex, both at the intrahemispheric and interhemispheric level. In the present study, TMS was used to examine age-related modulation of corticospinal function. Participants underwent hand function testing to examine possible links between TMS measures and manual ability. Participants consisted of healthy young (n=13) and senior (n=17) right-handed individuals. Hand function testing consisted of a battery of tests administered bilaterally to assess each participant’s dexterity, strength, movement speed and reaction time. The following TMS measures were assessed bilaterally: resting motor threshold, recruitment curve and silent periods of the contralateral and ipsilateral hand. Both young and senior subjects showed significant intermanual differences in most behavioral measures, favoring their dominant right hand. There was an age-related difference in TMS measures indicating a decline in intrahemispheric excitability and interhemispheric inhibition. A general trend linking specific TMS measures in the active state with age-related changes in hand function on the dominant hand was found. Our results suggest that TMS markers of corticospinal excitability can be used to predict declining hand function with age and thus could provide an early diagnosis of pathological aging.

Transcranial Magnetic Stimulation

Corticospinal tract

Aging

Hand function

Neurophysiology

Brain-Machine Interface for Reaching: Accounting for Target Size, Multiple Motor Plans, and Bimanual Coordination

Ifft, Peter James

January 2014

<p>Brain-machine interfaces (BMIs) offer the potential to assist millions of people worldwide suffering from immobility due to loss of limbs, paralysis, and neurodegenerative diseases. BMIs function by decoding neural activity from intact cortical brain regions in order to control external devices in real-time. While there has been exciting progress in the field over the past 15 years, the vast majority of the work has focused on restoring of motor function of a single limb. In the work presented in this thesis, I first investigate the expanded role of primary sensory (S1) and motor (M1) cortex during reaching movements. By varying target size during reaching movements, I discovered the cortical correlates of the speed-accuracy tradeoff known as Fitts' law. Similarly, I analyzed cortical motor processing during tasks where the motor plan is quickly reprogrammed. In each study, I found that parameters relevant to the reach, such as target size or alternative movement plans, could be extracted by neural decoders in addition to simple kinematic parameters such as velocity and position. As such, future BMI functionality could expand to account for relevant sensory information and reliably decode intended reach trajectories, even amidst transiently considered alternatives.</p><p> The second portion of my thesis work was the successful development of the first bimanual brain-machine interface. To reach this goal, I expanded the neural recordings system to enable bilateral, multi-site recordings from approximately 500 neurons simultaneously. In addition, I upgraded the experiment to feature a realistic virtual reality end effector, customized primate chair, and eye tracking system. Thirdly, I modified the tuning function of the unscented Kalman filter (UKF) to conjointly represent both arms in a single 4D model. As a result of widespread cortical plasticity in M1, S1, supplementary motor area (SMA), and posterior parietal cortex (PPC), the bimanual BMI enabled rhesus monkeys to simultaneously control two virtual limbs without any movement of their own body. I demonstrate the efficacy of the bimanual BMI in both a subject with prior task training using joysticks and a subject naïve to the task altogether, which simulates a common clinical scenario. The neural decoding algorithm was selected as a result of a methodical comparison between various neural decoders and decoder settings. I lastly introduce a two-stage switching model with a classify step and predict step which was designed and tested to generalize decoding strategies to include both unimanual and bimanual movements.</p> / Dissertation

Biomedical engineering

Neurosciences

brain-machine interfaces

neurophysiology

neuroprosthetics

Artificial neural nets: a critical analysis of their effectiveness as empirical technique for cognitive modelling.

Krebs, Peter Rudolf, School of History & Philosophy of Science, UNSW

January 2007

This thesis is concerned with the computational modelling and simulation of physiological structures and cognitive functions of brains through the use of artificial neural nets. While the structures of these models are loosely related to neurons and physiological structures observed in brains, the extent to which we can accept claims about how neurons and brains really function based on such models depends largely on judgments about the fitness of (virtual) computer experiments as empirical evidence. The thesis examines the computational foundations of neural models, neural nets, and some computational models of higher cognitive functions in terms of their ability to provide empirical support for theories within the framework of Parallel Distributed Processing (PDP). Models of higher cognitive functions in this framework are often presented in forms that hybridise top-down (e.g. employing terminology from Psychology or Linguistics) and bottom-up (neurons and neural circuits) approaches to cognition. In this thesis I argue that the use of terminology from either approach can blind us to the highly theory-laden nature of the models, and that this tends to produce overly optimistic evaluations of the empirical value of computer experiments on these models. I argue, further, that some classes of computational models and simulations based on methodologies that hybridise top-down and bottom-up approaches are ill-designed. Consequently, many of the theoretical claims based on these models cannot be supported by experiments with such models. As a result, I question the effectiveness of computer experiments with artificial neural nets as an empirical technique for cognitive modelling.

Cognitive neuroscience.

Cognition -- Physiology.

Brain -- Anatomy.

Brain -- Computer simulation.

Neurophysiology.

Eye Movement Strategies and Vision in Teleost Fish

Fritsches, Kerstin Anna

Unknown Date

This is a comparative study of eye movement behaviour of teleost fish from 5 families with diverse visual specialisations and oculomotor function. In chapter 3 I compared basic oculomotor parameters in three species of fish from the families Creediidae, Syngnathidae and Pinguipedidae, that show asynchronous eye movements and a fovea. All three species showed a close correlation between their specific retinal specialisation, oculomotor range and the lifestyles and feeding habits. Direction of gaze was correlated in the two independently moving eyes in both sandperch (Pinguipedidae) and pipefish (Syngnathidae) but not in the sandlance (Creediidae). Properties of spontaneous and fixational fast eye movements (saccades) in the species studied show many similarities to those found in other vertebrates. The apparent independence of the two eyes in the teleosts studied seem to set them apart from many other vertebrates, where eye movements are largely correlated with respect to each other. The results presented in chapter 4, however, reveal a regular switching of saccadic activity between the left and the right eye in sandlance, pipefish and sandperch, suggesting that the two eyes are in some way correlated. Since saccades are often a motor correlate of attention this finding suggests that these teleosts with asynchronous eye movements may show periodic shifts of attention while observing their environment. In chapter 5 the correlation between the two eyes was also tested during optokinetic nystagmus. This basic response shown by all animals stabilises the gaze against rotational head movements and translation. In most vertebrates the optokinetic response is tightly yoked in both eyes. This is also the case for the butterflyfish (Chaetodontidae) which shows strong yoking of the eyes during spontaneous eye movements. However some capacity for independent optokinesis in the two eyes was observed. Both sandlance and pipefish are capable of following two conflicting stimuli independently. However monocular occlusion in the pipefish unmasks a link between the two eyes, which is overridden when both eyes receive visual input. The sandlance never showed any correlation between eyes during optokinesis, even during monocular stimulation. This suggests that there are different levels of linkage between the two eyes in the oculomotor system of teleosts, depending on the visual input. One of the main functions of the oculomotor system in vertebrates and most invertebrates is to keep the image of the world relatively still on the retina. As shown in chapter 6 the sandlance breaks this universal rule of image stabilisation by showing large postsaccadic drifting eye movements as part of its normal oculomotor behaviour. In these animals, up to 40% of spontaneous saccades are followed by a drifting movement, either binocularly or in one eye only. The drifts are large and are always directed towards the most relaxed position of the eye, indicating that this form of eye movement is not visually driven. However the eye is visually responsive and saccades and an optokinetic response can be elicited during a drift. The drifting speed and the known acuity of the sandlance eye suggest that, during the drift, the image quality is not degraded. Several advantages of this unusual oculomotor behaviour can be related to the unusual optics and lifestyle of the sandlance. A unique modification of the eye muscles of billfish (Xiphiidae) maintains the eye and brain above ambient temperature; however the function of this adaptation and its effect on the oculomotor system is unknown. Chapter 7 aims to provide an insight into the visual abilities of billfish derived from anatomical observations of their retinal structure. The observations help explain the effect the increased retinal temperature might have for vision and eye movements. The blue marlin (Makaira nigricans) shows a well developed temporal area centralis and no visual streak, suggesting that a functional oculomotor system is required in this fish. A convergence of cones to ganglion cells at a ratio of at least 5:1 is present even in the area of highest acuity. The finding of two cone types suggest that the animal is capable of wavelength discrimination. Regional differences in size and composition of photoreceptors between dorsal and ventral retina potentially affect colour vision and sensitivity. The anatomical results suggest that sensitivity and spatial summation are of high priority to billfish. The possible function of the warm retina for increasing temporal resolution is discussed. These findings show the adaptability of the oculomotor system to suit the needs of different teleost lifestyles. However most of the parameters established for the oculomotor system of higher vertebrates also hold for teleosts.

Visual Ecology

Fish

Oculomotor Behaviour

Comparative Neurophysiology

Retina

Olfaction in mosquitoes : neuroanatomy and electrophysiology of the olfactory system /

Ghaninia, Majid,

January 2007

Diss. (sammanfattning) Alnarp : Sveriges lantbruksuniv., 2007. / Härtill 4 uppsatser.

The role of the amygdala and other forebrain structures in the immediate fear arousal produced by footshock exposure : a thesis submitted in partial fulfilment of the requirements for the degree of Master of Science in Psychology at the University of Canterbury /

Ganev, Jennifer.

January 2007

Thesis (M.Sc.)--University of Canterbury, 2007. / Typescript (photocopy). Includes bibliographical references (leaves 74-89). Also available via the World Wide Web.