游离神经元培养的异常检测和规律敏感性。

IF 3 3区医学 Q2 NEUROSCIENCES

Frontiers in Neural Circuits Pub Date : 2025-08-25 eCollection Date: 2025-01-01 DOI:10.3389/fncir.2025.1584322

Zhuo Zhang, Amit Yaron, Dai Akita, Tomoyo Isoguchi Shiramatsu, Zenas C Chao, Hirokazu Takahashi

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引用次数: 0

摘要

了解神经网络如何处理复杂的信息模式对于推进神经科学和人工智能至关重要。为了研究神经计算的基本原理，我们研究了游离神经元培养物（最原始的活神经网络之一）是否表现出超出刺激特异性适应和偏差检测的规律性敏感性。方法：我们记录了高分辨率CMOS微电极阵列培养的游离大鼠皮层神经元对古怪电刺激范式的活动。我们检查了使用n -甲基- d -天冬氨酸（NMDA）受体拮抗剂的药理学操作对反应的影响。为了评估规则敏感性，我们比较了可预测的周期性序列和随机序列刺激之间的神经反应。结果：在古怪的电刺激模式下，我们证实了神经元培养产生的失配反应（MMRs）具有真正的偏差检测，而不仅仅是适应。这些mmr依赖于n -甲基- d -天冬氨酸（NMDA）受体，类似于人类的失配阴性（MMN），已知其具有真正的偏差检测特性。至关重要的是，我们还显示了对刺激的统计规律的敏感性，这是一种以前只在完整的大脑中观察到的现象：在可预测的、周期性序列中的mmr比在随机和不可预测的异常刺激出现的常用序列中的mmr要小。讨论：这些结果挑战了传统观点，即需要分层结构的神经网络来处理复杂的时间模式，相反，偏差检测和规则敏感性是原始神经网络产生的固有特性。他们还为神经启发的人工智能系统的发展提出了新的方向，强调了在神经网络设计中结合自适应机制和时间动态的重要性。

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Deviance detection and regularity sensitivity in dissociated neuronal cultures.

Introduction: Understanding how neural networks process complex patterns of information is crucial for advancing both neuroscience and artificial intelligence. To investigate fundamental principles of neural computation, we examined whether dissociated neuronal cultures, one of the most primitive living neural networks, exhibit regularity sensitivity beyond mere stimulus-specific adaptation and deviance detection.

Methods: We recorded activity to oddball electrical stimulation paradigms from dissociated rat cortical neurons cultured on high-resolution CMOS microelectrode arrays. We examined the effects of pharmacological manipulation on responses using the N-methyl-D-aspartate (NMDA) receptor antagonist. To assess regularity sensitivity, we compared neural responses between predictable periodic sequences and random sequences of stimuli.

Results: In oddball electrical stimulation paradigms, we confirmed that the neuronal culture produced mismatch responses (MMRs) with true deviance detection beyond mere adaptation. These MMRs were dependent on the N-methyl-D-aspartate (NMDA) receptors, similar to mismatch negativity (MMN) in humans, which is known to have true deviance detection properties. Crucially, we also showed sensitivity to the statistical regularity of stimuli, a phenomenon previously observed only in intact brains: the MMRs in a predictable, periodic sequence were smaller than those in a commonly used sequence in which the appearance of the deviant stimulus was random and unpredictable.

Discussion: These results challenge the traditional view that a hierarchically structured neural network is required to process complex temporal patterns, suggesting instead that deviant detection and regularity sensitivity are inherent properties arising from the primitive neural network. They also suggest new directions for the development of neuro-inspired artificial intelligence systems, emphasizing the importance of incorporating adaptive mechanisms and temporal dynamics in the design of neural networks.

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来源期刊

Frontiers in Neural Circuits NEUROSCIENCES-

CiteScore

6.00

自引率

5.70%

发文量

135

审稿时长

4-8 weeks

期刊介绍： Frontiers in Neural Circuits publishes rigorously peer-reviewed research on the emergent properties of neural circuits - the elementary modules of the brain. Specialty Chief Editors Takao K. Hensch and Edward Ruthazer at Harvard University and McGill University respectively, are supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics and the public worldwide. Frontiers in Neural Circuits launched in 2011 with great success and remains a "central watering hole" for research in neural circuits, serving the community worldwide to share data, ideas and inspiration. Articles revealing the anatomy, physiology, development or function of any neural circuitry in any species (from sponges to humans) are welcome. Our common thread seeks the computational strategies used by different circuits to link their structure with function (perceptual, motor, or internal), the general rules by which they operate, and how their particular designs lead to the emergence of complex properties and behaviors. Submissions focused on synaptic, cellular and connectivity principles in neural microcircuits using multidisciplinary approaches, especially newer molecular, developmental and genetic tools, are encouraged. Studies with an evolutionary perspective to better understand how circuit design and capabilities evolved to produce progressively more complex properties and behaviors are especially welcome. The journal is further interested in research revealing how plasticity shapes the structural and functional architecture of neural circuits.