Your search keyword '"Yorita, Allison M"' showing total 6 results

1. A microfabricated, 3D-sharpened silicon shuttle for insertion of flexible electrode arrays through dura mater into brain.

Author

Joo, Hannah R, Joo, Hannah R, Fan, Jiang Lan, Chen, Supin, Pebbles, Jeanine A, Liang, Hexin, Chung, Jason E, Yorita, Allison M, Tooker, Angela C, Tolosa, Vanessa M, Geaghan-Breiner, Charlotte, Roumis, Demetris K, Liu, Daniel F, Haque, Razi, Frank, Loren M, Joo, Hannah R, Joo, Hannah R, Fan, Jiang Lan, Chen, Supin, Pebbles, Jeanine A, Liang, Hexin, Chung, Jason E, Yorita, Allison M, Tooker, Angela C, Tolosa, Vanessa M, Geaghan-Breiner, Charlotte, Roumis, Demetris K, Liu, Daniel F, Haque, Razi, and Frank, Loren M

Abstract

ObjectiveElectrode arrays for chronic implantation in the brain are a critical technology in both neuroscience and medicine. Recently, flexible, thin-film polymer electrode arrays have shown promise in facilitating stable, single-unit recordings spanning months in rats. While array flexibility enhances integration with neural tissue, it also requires removal of the dura mater, the tough membrane surrounding the brain, and temporary bracing to penetrate the brain parenchyma. Durotomy increases brain swelling, vascular damage, and surgical time. Insertion using a bracing shuttle results in additional vascular damage and brain compression, which increase with device diameter; while a higher-diameter shuttle will have a higher critical load and more likely penetrate dura, it will damage more brain parenchyma and vasculature. One way to penetrate the intact dura and limit tissue compression without increasing shuttle diameter is to reduce the force required for insertion by sharpening the shuttle tip.ApproachWe describe a novel design and fabrication process to create silicon insertion shuttles that are sharp in three dimensions and can penetrate rat dura, for faster, easier, and less damaging implantation of polymer arrays. Sharpened profiles are obtained by reflowing patterned photoresist, then transferring its sloped profile to silicon with dry etches.Main resultsWe demonstrate that sharpened shuttles can reliably implant polymer probes through dura to yield high quality single unit and local field potential recordings for at least 95 days. On insertion directly through dura, tissue compression is minimal.SignificanceThis is the first demonstration of a rat dural-penetrating array for chronic recording. This device obviates the need for a durotomy, reducing surgical time and risk of damage to the blood-brain barrier. This is an improvement to state-of-the-art flexible polymer electrode arrays that facilitates their implantation, particularly in multi-site recording ex

Published

2019

2. A microfabricated, 3D-sharpened silicon shuttle for insertion of flexible electrode arrays through dura mater into brain.

Author

Joo, Hannah R, Joo, Hannah R, Fan, Jiang Lan, Chen, Supin, Pebbles, Jeanine A, Liang, Hexin, Chung, Jason E, Yorita, Allison M, Tooker, Angela C, Tolosa, Vanessa M, Geaghan-Breiner, Charlotte, Roumis, Demetris K, Liu, Daniel F, Haque, Razi, Frank, Loren M, Joo, Hannah R, Joo, Hannah R, Fan, Jiang Lan, Chen, Supin, Pebbles, Jeanine A, Liang, Hexin, Chung, Jason E, Yorita, Allison M, Tooker, Angela C, Tolosa, Vanessa M, Geaghan-Breiner, Charlotte, Roumis, Demetris K, Liu, Daniel F, Haque, Razi, and Frank, Loren M

Abstract

ObjectiveElectrode arrays for chronic implantation in the brain are a critical technology in both neuroscience and medicine. Recently, flexible, thin-film polymer electrode arrays have shown promise in facilitating stable, single-unit recordings spanning months in rats. While array flexibility enhances integration with neural tissue, it also requires removal of the dura mater, the tough membrane surrounding the brain, and temporary bracing to penetrate the brain parenchyma. Durotomy increases brain swelling, vascular damage, and surgical time. Insertion using a bracing shuttle results in additional vascular damage and brain compression, which increase with device diameter; while a higher-diameter shuttle will have a higher critical load and more likely penetrate dura, it will damage more brain parenchyma and vasculature. One way to penetrate the intact dura and limit tissue compression without increasing shuttle diameter is to reduce the force required for insertion by sharpening the shuttle tip.ApproachWe describe a novel design and fabrication process to create silicon insertion shuttles that are sharp in three dimensions and can penetrate rat dura, for faster, easier, and less damaging implantation of polymer arrays. Sharpened profiles are obtained by reflowing patterned photoresist, then transferring its sloped profile to silicon with dry etches.Main resultsWe demonstrate that sharpened shuttles can reliably implant polymer probes through dura to yield high quality single unit and local field potential recordings for at least 95 days. On insertion directly through dura, tissue compression is minimal.SignificanceThis is the first demonstration of a rat dural-penetrating array for chronic recording. This device obviates the need for a durotomy, reducing surgical time and risk of damage to the blood-brain barrier. This is an improvement to state-of-the-art flexible polymer electrode arrays that facilitates their implantation, particularly in multi-site recording ex

Published

2019

3. Corrigendum: Basolateral amygdala rapid glutamate release encodes an outcome-specific representation vital for reward-predictive cues to selectively invigorate reward-seeking actions.

Author

Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, Wassum, Kate M, Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, and Wassum, Kate M

Published

2016

4. Corrigendum: Basolateral amygdala rapid glutamate release encodes an outcome-specific representation vital for reward-predictive cues to selectively invigorate reward-seeking actions.

Author

Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, Wassum, Kate M, Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, and Wassum, Kate M

Abstract

Scientific Reports 5: Article number: 12511; published online: 27 July 2015; updated: 15 February 2016 The original version of this Article contained an error in the Abstract. “These data the hypothesis that transient glutamate release in the BLA can encode the outcome-specific motivational information provided by reward-predictive stimuli”.

Published

2016

5. Basolateral amygdala rapid glutamate release encodes an outcome-specific representation vital for reward-predictive cues to selectively invigorate reward-seeking actions.

Author

Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, Wassum, Kate M, Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, and Wassum, Kate M

Abstract

Environmental stimuli have the ability to generate specific representations of the rewards they predict and in so doing alter the selection and performance of reward-seeking actions. The basolateral amygdala participates in this process, but precisely how is unknown. To rectify this, we monitored, in near-real time, basolateral amygdala glutamate concentration changes during a test of the ability of reward-predictive cues to influence reward-seeking actions (Pavlovian-instrumental transfer). Glutamate concentration was found to be transiently elevated around instrumental reward seeking. During the Pavlovian-instrumental transfer test these glutamate transients were time-locked to and correlated with only those actions invigorated by outcome-specific motivational information provided by the reward-predictive stimulus (i.e., actions earning the same specific outcome as predicted by the presented CS). In addition, basolateral amygdala AMPA, but not NMDA glutamate receptor inactivation abolished the selective excitatory influence of reward-predictive cues over reward seeking. These data support [corrected] the hypothesis that transient glutamate release in the BLA can encode the outcome-specific motivational information provided by reward-predictive stimuli.

Published

2015

6. Basolateral amygdala rapid glutamate release encodes an outcome-specific representation vital for reward-predictive cues to selectively invigorate reward-seeking actions.

Author

Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, Wassum, Kate M, Malvaez, Melissa, Malvaez, Melissa, Greenfield, Venuz Y, Wang, Alice S, Yorita, Allison M, Feng, Lili, Linker, Kay E, Monbouquette, Harold G, and Wassum, Kate M

Abstract

Environmental stimuli have the ability to generate specific representations of the rewards they predict and in so doing alter the selection and performance of reward-seeking actions. The basolateral amygdala participates in this process, but precisely how is unknown. To rectify this, we monitored, in near-real time, basolateral amygdala glutamate concentration changes during a test of the ability of reward-predictive cues to influence reward-seeking actions (Pavlovian-instrumental transfer). Glutamate concentration was found to be transiently elevated around instrumental reward seeking. During the Pavlovian-instrumental transfer test these glutamate transients were time-locked to and correlated with only those actions invigorated by outcome-specific motivational information provided by the reward-predictive stimulus (i.e., actions earning the same specific outcome as predicted by the presented CS). In addition, basolateral amygdala AMPA, but not NMDA glutamate receptor inactivation abolished the selective excitatory influence of reward-predictive cues over reward seeking. These data support [corrected] the hypothesis that transient glutamate release in the BLA can encode the outcome-specific motivational information provided by reward-predictive stimuli.

Published

2015