Wei Xu, Mixia Wang, Gucheng Yang, Fan Mo, Yaoyao Liu, Jin Shan, Luyi Jing, Ming Li, Juntao Liu, Shiya Lv, Yiming Duan, Meiqi Han, Zhaojie Xu, Yilin Song, Xinxia Cai
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引用次数: 0
Abstract
Navigating toward destinations with rewards is a common behavior among animals. The ventral tegmental area (VTA) has been shown to be responsible for reward coding and reward cue learning, and its response to other variables, such as kinematics, has also been increasingly studied. These findings suggest a potential relationship between animal navigation behavior and VTA activity. However, the deep location and small volume of the VTA pose significant challenges to the precision of electrode implantation, increasing the uncertainty of measurement results during animal navigation and thus limiting research on the role of the VTA in goal-directed navigation. To address this gap, we innovatively designed and fabricated low-curvature microelectrode arrays (MEAs) via a novel backside dry etching technique to release residual stress. Histological verification confirmed that low-curvature MEAs indeed improved electrode implantation precision. These low-curvature MEAs were subsequently implanted into the VTA of the rats to observe their electrophysiological activity in a freely chosen modified T-maze. The results of the behavioral experiments revealed that the rats could quickly learn the reward probability corresponding to the left and right paths and that VTA neurons were deeply involved in goal-directed navigation. Compared with those in no-reward trials, VTA neurons in reward trials presented a significantly greater firing rate and larger local field potential (LFP) amplitude during the reward-consuming period. Notably, we discovered place fields mapped by VTA neurons, which disappeared or were reconstructed with changes in the path-outcome relationship. These results provide new insights into the VTA and its role in goal-directed navigation. Our designed and fabricated low-curvature microelectrode arrays can serve as a new device for precise deep brain implantation in the future.
向有奖励的目的地导航是动物的一种常见行为。腹侧被盖区(VTA)被证明负责奖励编码和奖励线索学习,其对运动学等其他变量的反应也被越来越多地研究。这些研究结果表明,动物导航行为与 VTA 活动之间存在潜在关系。然而,VTA位置深且体积小,给电极植入的精确性带来了巨大挑战,增加了动物导航过程中测量结果的不确定性,从而限制了对VTA在目标定向导航中作用的研究。为了弥补这一不足,我们通过新型背面干蚀刻技术释放残余应力,创新性地设计和制造了低曲率微电极阵列(MEA)。组织学验证证实,低曲率 MEA 确实提高了电极植入的精度。随后将这些低曲率 MEA 植入大鼠的 VTA,观察它们在自由选择的改良 T 型迷宫中的电生理活动。行为实验的结果表明,大鼠能很快学会与左右路径相对应的奖励概率,VTA神经元深度参与了目标定向导航。与无奖赏试验中的神经元相比,奖赏试验中的VTA神经元在奖赏消耗期表现出明显更高的发射率和更大的局域场电位(LFP)振幅。值得注意的是,我们发现 VTA 神经元映射的地点场会随着路径-结果关系的变化而消失或重建。这些结果为我们提供了有关 VTA 及其在目标定向导航中作用的新见解。我们设计和制造的低曲率微电极阵列可作为未来精确脑深部植入的新设备。
期刊介绍:
Microsystems & Nanoengineering is a comprehensive online journal that focuses on the field of Micro and Nano Electro Mechanical Systems (MEMS and NEMS). It provides a platform for researchers to share their original research findings and review articles in this area. The journal covers a wide range of topics, from fundamental research to practical applications. Published by Springer Nature, in collaboration with the Aerospace Information Research Institute, Chinese Academy of Sciences, and with the support of the State Key Laboratory of Transducer Technology, it is an esteemed publication in the field. As an open access journal, it offers free access to its content, allowing readers from around the world to benefit from the latest developments in MEMS and NEMS.