Encoding of rat working memory by power of multi-channel local field potentials via sparse non-negative matrix factorization 被引量：1

Encoding of rat working memory by power of multi-channel local field potentials via sparse non-negative matrix factorization

原文传递

导出

摘要 Working memory plays an important role in human cognition. This study investigated how working memory was encoded by the power of multichannel local field potentials （LFPs） based on sparse non negative matrix factorization （SNMF）. SNMF was used to extract features from LFPs recorded from the prefrontal cortex of four SpragueDawley rats during a memory task in a Y maze, with 10 trials for each rat. Then the powerincreased LFP components were selected as working memoryrelated features and the other components were removed. After that, the inverse operation of SNMF was used to study the encoding of working memory in the time frequency domain. We demonstrated that theta and gamma power increased significantly during the working memory task. The results suggested that postsynaptic activity was simulated well by the sparse activity model. The theta and gamma bands were meaningful for encoding working memory. Working memory plays an important role in human cognition. This study investigated how working memory was encoded by the power of multichannel local field potentials （LFPs） based on sparse non negative matrix factorization （SNMF）. SNMF was used to extract features from LFPs recorded from the prefrontal cortex of four SpragueDawley rats during a memory task in a Y maze, with 10 trials for each rat. Then the powerincreased LFP components were selected as working memoryrelated features and the other components were removed. After that, the inverse operation of SNMF was used to study the encoding of working memory in the time frequency domain. We demonstrated that theta and gamma power increased significantly during the working memory task. The results suggested that postsynaptic activity was simulated well by the sparse activity model. The theta and gamma bands were meaningful for encoding working memory.

作者 Xu Liu Tiao-Tiao Liu Wen-Wen Bai Hu Yi Shuang-Yan Li Xin Tian

机构地区 School of Biomedical Engineering Research Center of Basic Medicine

出处《Neuroscience Bulletin》 SCIE CAS CSCD 2013年第3期279-286,共8页 神经科学通报（英文版）

基金 supported by the National Natural Science Foundation of China (61074131 and 91132722) the Doctoral Fund of the Ministry of Education of China (21101202110007)

关键词 sparse non-negative matrix factorization multi-channel local field potentials working memory prefrontal cortex sparse non-negative matrix factorization multi-channel local field potentials working memory prefrontal cortex

分类号 Q42 [生物学—神经生物学] TN911.7 [电子电信—通信与信息系统]

引文网络
相关文献

参考文献1

1石金龙,骆志刚.非负矩阵分解算法及其在生物信息学中的应用研究[J].计算机工程与科学,2010,32(8):117-123. 被引量：6

二级参考文献61

1Yeung M K, Tegner J, Collins J J. Reverse Engineering Gene Networks Using Singular Value Decomposition and Robust Regression[J]. Proceedings of the National Academy of Sciences, 2002,99(9) : 6163-6168.
2Yeung K Y, Ruzzo W L. Principal Component Analysis for Clustering Gene Expression Data [J]. Bioinformatics, 2001, 17(9):763-774.
3Liebermeister W, IAnear Modes of Gene Expression Determined by Independent Component Analysis[J]. Bioinformatics, 2002,18(1) : 51-60.
4Liao J C, Boscolo R, Yang Y L, et al. Network Component Analysis: Reconstruction of Regulatory Signals in Biological Systems[J]. Proceedings of the National Academy of Sciences, 2003,100(26) : 15522-15527.
5Lee D D,Seung H S. Learning the Parts of Objects by Nonnegative Matrix Factorization[J]. Nature, 1999,401 (6755) : 788-791.
6Paatero P, Tapper U. Positive Matrix Factorization: A Nonnegative Factor Model with Optimal Utilization of Error Estimates of Data Values[J]. Environmetries, 1994,5 ( 2 ) : 111- 126.
7Paatero P. I.east Squares Formulation of Robust Non-negative Factor Analysis[J]. Chemometrics and Intelligent Laboratory Systems, 1997,37 ( 1 ) : 22-35.
8Lee D D, Seung H S. Unsupervised Learning by Convex and Conic Coding[J]. Advances in Neural Information Processing Systems, 1997,1997(9) : 515-521.
9Lee D D,Sebastian S H. Algorithms for Non-negative Matrix Factorization[J]. Advances in Neural Information Processing Systems, 2001,2001 (13):556-562.
10Li S Z, Hou Xinwen, Zhang Hongjiang, et al. Learning Spatially Localized, Parts-Based Representation [C]//Proc of IEEE Conf on Computer Vision and Pattern Recognition, 2001 : 207-212.

共引文献5

1乔艳花,张晓琴.处理核磁共振数据的一种改进非负矩阵分解算法[J].太原师范学院学报（自然科学版）,2012,11(4):72-74.
2孙泽强,谢红薇,郝晓燕.NMF模型在挖掘基因功能关系中的研究与应用[J].计算机工程与设计,2014,35(4):1471-1475. 被引量：2
3任重鲁,李金明.非负矩阵分解在微阵列数据分类和聚类发现中的应用[J].计算机工程与科学,2014,36(7):1389-1397. 被引量：5
4谢昊,邱娟,张传林.非负矩阵分解(NMF)初值选取的延展算法[J].高等学校计算数学学报,2015,37(4):370-384.
5高树南,林鹭.基于非负矩阵分解的房地产评估模型[J].应用数学与计算数学学报,2016,30(2):280-289.

同被引文献5

1史加荣,焦李成,尚凡华.不完全非负矩阵分解的加速算法[J].电子学报,2011,39(2):291-295. 被引量：13
2同鸣,张伟,张建龙,陈涛.一种基于部分基矩阵稀疏约束非负矩阵分解的抵抗大强度剪切攻击视频水印构架[J].电子与信息学报,2012,34(8):1819-1826. 被引量：10
3方蔚涛,马鹏,成正斌,杨丹,张小洪.二维投影非负矩阵分解算法及其在人脸识别中的应用[J].自动化学报,2012,38(9):1503-1512. 被引量：32
4姜伟,李宏,余震国,杨炳儒.稀疏约束图正则非负矩阵分解[J].计算机科学,2013,40(1):218-220. 被引量：13
5施蓓琦,刘春,孙伟伟,陈能.应用稀疏非负矩阵分解聚类实现高光谱影像波段的优化选择[J].测绘学报,2013,42(3):351-358. 被引量：16

引证文献1

1王万良,蔡竞.稀疏约束下非负矩阵分解的增量学习算法[J].计算机科学,2014,41(8):241-244. 被引量：8

二级引证文献8

1聂规划,于珊珊,刘平峰,游怀杰.基于相似度的信息颗粒更新方法[J].武汉理工大学学报（信息与管理工程版）,2015,37(3):304-307.
2陆成刚.与数据挖掘相关的整数矩阵的左右可逆性研究[J].计算机科学,2016,43(5):247-251.
3汪金涛,曹玉东,孙福明.稀疏约束图正则非负矩阵分解的增量学习算法[J].计算机应用,2017,37(4):1071-1074. 被引量：3
4孙静,蔡希彪,姜小燕,孙福明.基于图正则化和稀疏约束的增量型非负矩阵分解[J].计算机科学,2017,44(6):298-305. 被引量：4
5蔡竞,王万良,郑建炜,李吉明.增量式鉴别非负矩阵分解算法及其在人脸识别中的应用[J].图学学报,2017,38(5):715-721. 被引量：4
6邓万宇,耿美娜,李建强.不完备多视图的在线反向图正则化聚类[J].计算机与数字工程,2023,51(5):1005-1011.
7杨亮东,赵妍杰,潘正红.稀疏约束的L21增量式非负矩阵分解研究[J].科技资讯,2024,22(12):240-244.
8蔡竞,张嘉琪,钱康.改进增量式非负矩阵分解算法及其在人脸识别中的应用[J].信息通信,2016,29(7):4-8. 被引量：1

1Zou,YW,周素芳.数字HDTV地面广播的源编码[J].电子工程,1994(1):52-53.
2荣风静.Working Memory in Language Use[J].科技信息,2008(15):235-235.
3数字[J].数字印刷,2015(1):14-15.
4许红.上海贝尔“多屏”方案推动三网融合分步实现[J].邮电设计技术,2010(4):74-74.
5多屏融合：内容安全是关键[J].世界广播电视,2012,26(10):10-10.
6Gartner发布2010年前十大半导体厂排名[J].中国集成电路,2011,20(5):10-10.
75月底我国有线数字电视用户达5125.1万[J].中国有线电视,2009(7):752-752.
8阎建新.低比特率高质量数字声广播源编码[J].无线电通信技术,1992,18(5):310-317.
9王真,郑旭媛,马东华.基于压缩感知的局部场电位信号重构算法研究[J].计算机仿真,2013,30(4):200-203. 被引量：4
10孙艳,孙敏.数字音频广播(DAB)的特点和应用领域[J].中国有线电视,2010(12):1393-1395.

Neuroscience Bulletin

2013年第3期

浏览历史

内容加载中请稍等...