Previous studies have demonstrated that a rich, stimulating environment results in both anatomic and physiologic changes in the cerebral cortex. In addition to generalized sensory experience, training on perceptual learning tasks also alters neurophysiologic responses in sensory and motor cortex. The effects of both enrichment and training on responses from auditory cortex neurons are examined in this dissertation. Although there is a vast literature spanning almost three decades on the anatomic and morphologic effects of enrichment, comparatively fewer studies have focused on the neurophysiologic consequences of enrichment. For example, neurophysiologic effects of enrichment have been demonstrated in visual (Beaulieu and Cynader 1990a, b) and somatosensory (Coq and Xerri 1998) cortex. In these studies, enrichment sharpened orientation tuning in visual cortex and increased the area of forepaw representation in somatosensory cortex. The effects of enrichment on the processing of auditory cortex neurons are not known. In the first part of my dissertation, the effects of enrichment on the auditory cortex are documented. Changes in spectral and temporal responses from primary auditory cortex (A1) neurons of enriched rats were compared to responses from rats in standard conditions using multi-unit recordings. Enrichment dramatically enhanced cortical responses across A1, increased frequency selectivity and sensitivity and altered temporal processing without affecting cortical map reorganization (Engineer et al. 2004). The next study was designed to document the effects of auditory discrimination training on responses from auditory cortex neurons. Both animals and humans get better at discrimination tasks with practice. More recently, these studies have been combined with electrophysiological recordings (unit recording, evoked potentials, fMRI) to probe task specific effects on cortical responses. The second part of this dissertation documents the neurophysiologic consequences of auditory sequence learning on rat A1 neurons.; The results of these and earlier studies indicate that exposure to a rich, stimulating environments or training on perceptual learning tasks can significantly alter sensory information processing of cortical neurons. Although the exact consequences of plasticity on cortical development or recovery from injury are not clear, numerous studies suggest that environmental enrichment and/or behavioral training may be useful remediation strategies in promoting recovery from neurological disability.
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机译:先前的研究表明,丰富而刺激的环境会导致大脑皮层的解剖和生理变化。除了一般的感官经验外,对知觉学习任务的培训还会改变感觉和运动皮层的神经生理反应。本文研究了丰富和训练对听觉皮层神经元反应的影响。尽管有将近三十年的大量文献涉及富集的解剖学和形态学影响,但相对较少的研究集中于富集的神经生理后果。例如,视觉皮层(Beaulieu and Cynader 1990a,b)和体感皮层(Coq and Xerri 1998)已证明了丰富的神经生理作用。在这些研究中,富集增强了视觉皮层的方向调整,并增加了体感皮层的前爪代表区域。富集对听觉皮层神经元加工的影响尚不清楚。在论文的第一部分中,记录了富集对听觉皮层的影响。使用多单位记录,将来自富足大鼠的主听皮层(A1)神经元的光谱和时间响应变化与标准条件下大鼠的响应进行比较。浓缩显着增强了整个A1的皮层反应,增加了频率选择性和灵敏度,并改变了时间处理,而不会影响皮层图的重组(Engineer等,2004)。下一项研究旨在记录听觉歧视训练对听觉皮层神经元反应的影响。无论是动物还是人类,在实践中都可以更好地进行辨别任务。最近,这些研究已与电生理记录(单位记录,诱发电位,fMRI)相结合,以探究特定任务对皮层反应的影响。本文的第二部分记录了听觉序列学习对大鼠A1神经元的神经生理后果。这些研究和早期研究的结果表明,暴露于丰富的刺激性环境或接受知觉学习任务的培训会大大改变皮质神经元的感觉信息处理。尽管可塑性对皮层发育或从损伤中恢复的确切后果尚不清楚,但大量研究表明,环境丰富和/或行为训练可能是促进神经功能障碍恢复的有用补救策略。
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