Probabilistic cytoarchitectonic map of Interposed Nucleus (Cerebellum) (v6.2)

This dataset contains the distinct architectonic Interposed Nucleus (Cerebellum) in the individual, single subject template of the MNI Colin 27 as well as the MNI ICBM 152 2009c nonlinear asymmetric reference space. As part of the Julich-Brain cytoarchitectonic atlas, the area was identified using classical histological criteria and quantitative cytoarchitectonic analysis on cell-body-stained histological sections of 10 human postmortem brains obtained from the body donor program of the University of Düsseldorf. The results of the cytoarchitectonic analysis were then mapped to both reference spaces, where each voxel was assigned the probability to belong to Interposed Nucleus (Cerebellum). The probability map of Interposed Nucleus (Cerebellum) is provided in the NifTi format for each brain reference space and hemisphere. The Julich-Brain atlas relies on a modular, flexible and adaptive framework containing workflows to create the probabilistic brain maps for these structures. Note that methodological improvements and integration of new brain structures may lead to small deviations in earlier released datasets. Other available data versions of Interposed Nucleus (Cerebellum): Tellmann et al. (2019) [Data set, v6.0] [DOI: 10.25493/8MRR-JHC](https://doi.org/10.25493%2F8MRR-JHC) The most probable delineation of Interposed Nucleus (Cerebellum) derived from the calculation of a maximum probability map of all currently released Julich-Brain brain structures can be found here: Amunts et al. (2019) [Data set, v1.13] [DOI: 10.25493/Q3ZS-NV6](https://doi.org/10.25493%2FQ3ZS-NV6) Amunts et al. (2019) [Data set, v1.18] [DOI: 10.25493/8EGG-ZAR](https://doi.org/10.25493%2F8EGG-ZAR) Amunts et al. (2020) [Data set, v2.2] [DOI: 10.25493/TAKY-64D](https://doi.org/10.25493%2FTAKY-64D) Amunts et al. (2020) [Data set, v2.4] [DOI: 10.25493/A7Y0-NX9](https://doi.org/10.25493%2FA7Y0-NX9) Amunts et al. (2020) [Data set, v2.5] [DOI: 10.25493/8JKE-M53](https://doi.org/10.25493/8JKE-M53) Amunts et al. (2021) [Data set, v2.6] [DOI: 10.25493/KJQN-AM0](https://doi.org/10.25493%2FKJQN-AM0)

本数据集包含适配个体单被试模板的、经细胞构筑学定义的小脑间位核（Interposed Nucleus (Cerebellum)）结构，其适配的标准空间涵盖MNI Colin 27以及MNI ICBM 152 2009c非线性非对称参考空间。本数据集作为Julich-Brain细胞构筑图谱的一部分，该区域的鉴定基于经典组织学标准，以及对10例取自杜塞尔多夫大学遗体捐赠项目的人类死后大脑的胞体染色组织切片开展的定量细胞构筑分析。随后，将细胞构筑分析的结果映射至上述两个参考空间，每个体素都会被赋予属于小脑间位核的概率。针对每个大脑参考空间与脑半球，小脑间位核的概率图谱均以NIfTI格式提供。Julich-Brain图谱依托模块化、灵活且自适应的框架，该框架包含用于生成此类结构概率脑图谱的工作流。请注意，方法学改进与新脑结构的整合可能会导致早期发布的数据集出现细微偏差。小脑间位核的其他可用数据版本包括：Tellmann等人（2019）[数据集，v6.0] [DOI: 10.25493/8MRR-JHC](https://doi.org/10.25493%2F8MRR-JHC)。由当前已发布的全部Julich-Brain脑结构的最大概率图谱计算得到的小脑间位核最可靠划定边界可在此处获取：Amunts等人（2019）[数据集，v1.13] [DOI: 10.25493/Q3ZS-NV6](https://doi.org/10.25493%2FQ3ZS-NV6)；Amunts等人（2019）[数据集，v1.18] [DOI: 10.25493/8EGG-ZAR](https://doi.org/10.25493%2F8EGG-ZAR)；Amunts等人（2020）[数据集，v2.2] [DOI: 10.25493/TAKY-64D](https://doi.org/10.25493%2FTAKY-64D)；Amunts等人（2020）[数据集，v2.4] [DOI: 10.25493/A7Y0-NX9](https://doi.org/10.25493%2FA7Y0-NX9)；Amunts等人（2020）[数据集，v2.5] [DOI: 10.25493/8JKE-M53](https://doi.org/10.25493/8JKE-M53)；Amunts等人（2021）[数据集，v2.6] [DOI: 10.25493/KJQN-AM0](https://doi.org/10.25493%2FKJQN-AM0)