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Cover Image, Volume 531, Issue 18 封面图片,第 531 卷第 18 期
Pub Date : 2023-12-30 DOI: 10.1002/cne.25573
Gene J. Blatt, Cheryl Brandenburg, Alexandros Poulopoulos
The cover image is based on the Research Article India ink to 3D imaging: The legacy of Dr. Deepak “Dee” N. Pandya and his influence on generations of neuroanatomists by Gene J. Blatt et al., https://doi.org/10.1002/cne.25551.
封面图片来自研究文章《从印度墨水到三维成像》:Deepak "Dee" N. Pandya 博士的遗产及其对几代神经解剖学家的影响》,作者 Gene J. Blatt 等,https://doi.org/10.1002/cne.25551。
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引用次数: 0
Cytoarchitectonic and connection stripes in the dysgranular insular cortex in the macaque monkey 猕猴发育不良岛叶皮层的细胞结构和连接条纹
Pub Date : 2023-12-17 DOI: 10.1002/cne.25571
Matthias S. Krockenberger, Tatianna O. Saleh-Mattesich, Henry C. Evrard
The insula has been classically divided into broad granular, dysgranular, and agranular architectonic sectors. We previously proposed a novel partition, dividing each sector into four to seven sharply delimited architectonic areas, with the dysgranular areas being possibly further subdivided into subtle horizontal partitions or “stripes.” In architectonics, discrete subparcellations are prone to subjective variability and need being supported with additional neuroanatomical methods. Here, using a secondary analysis of indirect connectional data in the rhesus macaque monkey, we examined the spatial relationship between the dysgranular architectonic stripes and tract-tracing labeling patterns produced in the insula with injections of neuronal tracers in other cortical regions. The injections consistently produced sharply delimited patches of anterograde and/or retrograde labeling, which formed stripes across consecutive coronal sections of the insula. While the overall pattern of labeling on individual coronal sections varied with the injection site, the boundaries of the patches consistently coincided with architectonic boundaries on an adjacent cyto- (Nissl) and/or myelo- (Gallyas) architectonic section. This overlap supports the existence of a fine dysgranular stripe-like partition of the primate insula, with possibly major implications for interoceptive processing in primates including humans. The modular organization of the insula could underlie a serial stream of integration from a dorsal primary interoceptive cortex toward progressively more ventral egocentric “self-agency” and allocentric “social” dysgranular processing units.
岛叶被经典地划分为广义的颗粒区、粒状区和粒状区。我们之前提出了一种新的划分方法,将每个扇区分为四到七个界限分明的结构区,粒状结构区可能会进一步细分为微妙的水平分区或 "条纹"。在构架学中,离散的细分区域容易产生主观变异,因此需要更多神经解剖学方法的支持。在此,我们利用对猕猴间接连接数据的二次分析,研究了在其他皮层区域注射神经元示踪剂后,在岛叶产生的粒状结构不良条纹和束描标记模式之间的空间关系。注射过程中始终会产生界限清晰的前向和/或逆行标记斑块,这些斑块在脑岛的连续冠状切片上形成条纹。虽然各个冠状切片上标记的整体模式因注射部位而异,但斑块的边界始终与相邻细胞(Nissl)和/或髓(Gallyas)结构切片上的结构边界相吻合。这种重叠证明灵长类脑岛存在细小的粒状条纹状分区,可能对包括人类在内的灵长类动物的感知间处理有重大影响。岛叶的模块化组织可能是背侧初级感知间皮层向腹侧以自我为中心的 "自我代理 "和以分配为中心的 "社会 "粒状突触处理单元的序列整合流的基础。
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引用次数: 0
Comparison of monkey and human retrosplenial neurocytology 猴子和人类后脾神经细胞学的比较
Pub Date : 2023-12-07 DOI: 10.1002/cne.25561
Brent A. Vogt, Douglas L. Rosene
Retrosplenial cortex (RSC) has unique problems for human neuroimaging studies as its divisions are small, at the lower end of functional scanner spatial resolution, and it is buried in the callosal sulcus. The present study sought to define the cytoarchitecture of RSC in human and monkey brains along its entire anteroposterior extent. The results show anterior extensions, a newly defined dichotomy of area 30, a new area p30, and an area p29v in monkey that differentiates into three divisions in human. Accordingly, anterior (a), intermediate (i), and posterior (p) divisions of areas 29l, 29m, 30l, and 30m were identified. Posterior area 29 has higher neuron packing in the granular layer than anterior and intermediate divisions of area 29. A newly detected dysgranular area p30 has larger neurons in layers II–IIIab than a30 and i30 and with substantially higher NFP expression in layer IIIab of posterior areas than areas a30 and i30. Medial area 30 has larger pyramids and higher NFP expression in all layers than area 30l. The new area p30 was seen between areas p29m and p30I in both species. Finally, a ventral area p29v is present in monkeys. This latter area appears to differentiate into three divisions in human with the most extensive granular layer adjacent to layer I in p29vm and p29vl. Functional imaging has identified pRSC as part of a cognitive map which is engaged in spatial navigation and localization of personally relevant objects.
后脾皮层(RSC)在人类神经成像研究中存在独特的问题,因为它的分部很小,处于功能扫描仪空间分辨率的低端,而且埋藏在胼胝体沟中。本研究试图确定人脑和猴脑 RSC 沿着其整个前后方向的细胞结构。研究结果表明,猴脑中的前部扩展区、新定义的二分区 30 区、新的 p30 区和 p29v 区在人脑中分为三部分。相应地,29l区、29m区、30l区和30m区的前部(a)、中间部(i)和后部(p)也被确定下来。与 29 区的前部和中部相比,29 区后部的颗粒层神经元密度更高。新发现的颗粒发育不良区 p30 在 II-IIIab 层的神经元数量多于 a30 和 i30,在后部区域 IIIab 层的 NFP 表达量远高于 a30 和 i30。与 30l 区相比,内侧 30 区的金字塔更大,各层的 NFP 表达也更高。在两个物种中,p29m 和 p30I 区域之间出现了新的区域 p30。最后,猴子出现了腹侧区域 p29v。在人类中,后一区域似乎可分为三个部分,在 p29vm 和 p29vl 中,最广泛的颗粒层紧邻第 I 层。功能成像已确定 pRSC 是认知地图的一部分,它参与空间导航和个人相关对象的定位。
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引用次数: 0
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The Journal of Comparative Neurology
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