{"id":3683,"date":"2016-09-04T21:40:50","date_gmt":"2016-09-04T12:40:50","guid":{"rendered":"http:\/\/www.is.doshisha.ac.jp\/news\/?p=3683"},"modified":"2016-09-04T21:40:50","modified_gmt":"2016-09-04T12:40:50","slug":"%e3%80%90%e9%80%9f%e5%a0%b1%e3%80%91%e3%80%80neuroinformatics-2016","status":"publish","type":"post","link":"https:\/\/is.doshisha.ac.jp\/news\/?p=3683","title":{"rendered":"\u3010\u901f\u5831\u3011\u3000Neuroinformatics 2016"},"content":{"rendered":"<p>\u30a4\u30ae\u30ea\u30b9\u30fb\u30ec\u30c7\u30a3\u30f3\u30b0\u3067\u958b\u50ac\u3055\u308c\u305f\u3000<a href=\"http:\/\/neuroinformatics2016.org\/\">Neuroinformatics 2016<\/a> \u306b\u7814\u7a76\u5ba4\u304b\u3089\u4e0b\u8a18\u306e3\u540d\u304c\u767a\u8868\u3057\u307e\u3057\u305f\u3002<\/p>\n<ul>\n<li>M1 \u8429\u539f\u3000\u91cc\u5948\u00a0Functional connectivity analysis of working memory during a mental arithmetic task<\/li>\n<li>M1 \u5409\u6b66\u3000\u6c99\u898f<\/li>\n<li>M1 \u7389\u57ce\u3000\u8cb4\u4e5f\u00a0Region-of-interest estimation using convolutional neural\u00a0network and long short-term memory for functional\u00a0near-infrared spectroscopy data<\/li>\n<\/ul>\n<p><!--more--><br \/>\n\u3010\u6982\u8981\u3011<br \/>\nNeuroinformatics \u306fNeuro Science + Informatics\u3067\u3042\u308a\u3001\u795e\u7d4c\u79d1\u5b66\u306b\u95a2\u9023\u3059\u308b\u8a08\u7b97\u30e2\u30c7\u30eb\u3001\u89e3\u6790\u624b\u6cd5\u3001\u304a\u3088\u3073\u305d\u308c\u3089\u306b\u95a2\u9023\u3059\u308b\u7814\u7a76\u9818\u57df\u3067\u3059\u3002<br \/>\nNeuroinformatics 2016\u306f\u3001Neuroinformatics \u306b\u95a2\u9023\u3057\u305f\u7814\u7a76\u3092\u8b70\u8ad6\u3059\u308b\u5b66\u4f1a\u3067\u30012016\u5e74\u306f\u30a4\u30ae\u30ea\u30b9\u30fb\u30ec\u30c7\u30a3\u30f3\u30b0\u306e\u30ec\u30c7\u30a3\u30f3\u30b0\u5927\u5b66\u3067\u958b\u50ac\u308c\u307e\u3057\u305f\u3002<br \/>\n\u30ec\u30c7\u30a3\u30f3\u30b0\u306f\u30a4\u30ae\u30ea\u30b9\u306e\u5357\u3001\u30ed\u30f3\u30c9\u30f3\u306e\u897f\u306e\u4e2d\u90fd\u5e02\u3067\u3001\u6700\u8fd1\u306fIT\u7523\u696d\u304c\u96c6\u7a4d\u3057\u3066\u3044\u307e\u3059\u3002<br \/>\n\u6bce\u5e74\u3001\u590f8\u6708\u306b\u958b\u50ac\u3055\u308c\u308b\u91ce\u5916\u30ed\u30c3\u30af\u30fb\u30d5\u30a7\u30b9\u30c6\u30a3\u30d0\u30eb\u3000\u30ec\u30c7\u30a3\u30f3\u30b0\uff06\u30ea\u30fc\u30ba\u30fb\u30d5\u30a7\u30b9\u30c6\u30a3\u30d0\u30eb\u3000\u304c\u6709\u540d\u3067\u65e5\u672c\u306e\u30ed\u30c3\u30af\u30d5\u30a7\u30b9\u30c6\u30a3\u30d0\u30eb\u3082\u3053\u306e\u30d5\u30a7\u30b9\u3092\u624b\u672c\u306b\u3057\u3066\u3044\u308b\u3002<br \/>\nNeuroinformatics \u306e\u5206\u91ce\u3067\u306f\u3001\u795e\u7d4c\u79d1\u5b66\u306b\u95a2\u9023\u3059\u308b\u8a08\u7b97\u30e2\u30c7\u30eb\u3001\u89e3\u6790\u624b\u6cd5\u3082\u91cd\u8981\u3067\u3042\u308b\u304c\u3001\u305d\u308c\u3089\u306e\u30e2\u30c7\u30eb\u3084\u89e3\u6790\u65b9\u6cd5\u3092\u5e83\u304f\u5171\u6709\u3059\u308b\u305f\u3081\u306b\u306f\u3001\u305d\u308c\u3089\u3092\u5229\u7528\u3059\u308b\u30c7\u30fc\u30bf\u3092\u95a2\u4fc2\u8005\u3067\u540c\u3058\u30d5\u30a9\u30fc\u30de\u30c3\u30c8\u3067\u5171\u6709\u3059\u308b\u3053\u3068\u304c\u975e\u5e38\u306b\u91cd\u8981\u3067\u3042\u308b\u3002\u3053\u306e\u56fd\u969b\u4f1a\u8b70\u3067\u306f\u3001\u305d\u308c\u3089\u306e\u5185\u5bb9\u306b\u3064\u3044\u3066\u3082\u8b70\u8ad6\u304c\u884c\u308f\u308c\u308b\u73cd\u3057\u3044\u4f1a\u8b70\u3067\u3042\u308b\u3002<br \/>\nNeuroinformatics \u306f\u53c2\u52a0\u8005\u304c500\u4eba\u7a0b\u5ea6\u306e\u3053\u3058\u3093\u307e\u308a\u3068\u3057\u305f\u5b66\u4f1a\u3067\u3042\u308a\u3001KeyNote\u3068Presentaion, Poster\u304b\u3089\u69cb\u6210\u3055\u308c\u30012\u65e5\u9593\u306b\u308f\u305f\u3063\u3066\u3000\u6700\u59272\u30bb\u30c3\u30b7\u30e7\u30f3\u3067\u30d7\u30ed\u30b0\u30e9\u30e0\u304c\u69cb\u6210\u3055\u308c\u3066\u3044\u308b\u3002<br \/>\n\u3010\u57fa\u8abf\u8b1b\u6f14\u3011<br \/>\n2\u65e5\u9593\u306712\u30bb\u30c3\u30b7\u30e7\u30f3\u304c\u884c\u308f\u308c\u3001\u5404\u30bb\u30c3\u30b7\u30e7\u30f3\u306b1\u4ef6\u306e\u57fa\u8abf\u8b1b\u6f14\u304c\u3042\u3063\u305f\u3002<br \/>\n\u3010\u4e00\u822c\u8b1b\u6f14\u3011<br \/>\n\u5404\u30bb\u30c3\u30b7\u30e7\u30f3\u3067\u6570\u4ef6\u306e\u4e00\u822c\u8b1b\u6f14\u304c\u884c\u308f\u308c\u305f\u3002<br \/>\n\u9762\u767d\u3044\u306e\u306f\u3001\u5404\u30bb\u30c3\u30b7\u30e7\u30f3\u7d42\u4e86\u5f8c\u306b\u3001\u8b1b\u6f14\u3092\u884c\u3063\u305f\u57fa\u8abf\u8b1b\u6f14\u8005\u3001\u4e00\u822c\u8b1b\u6f14\u8005\u304c\u3000\u5168\u54e1\u53c2\u52a0\u3057\u3001\u30d1\u30cd\u30eb\u30c7\u30a3\u30b9\u30ab\u30c3\u30b7\u30e7\u30f3\u3092\u884c\u3046\u3053\u3068\u3067\u3042\u308b\u3002<br \/>\n\u4f1a\u5834\u304b\u3089\u3082\u8cea\u554f\u3092\u53d7\u3051\u4ed8\u3051\u3001\u30d7\u30ec\u30bc\u30f3\u30bf\u30fc\u304c\u7b54\u3048\u308b\u3068\u3044\u3046\u304a\u3082\u3057\u308d\u3044\u30b9\u30bf\u30a4\u30eb\u3067\u3042\u3063\u305f\u3002<br \/>\n\u3010\u30dd\u30b9\u30bf\u30fc\u3011<br \/>\n\u4f1a\u5834\u3092\u5909\u3048\u3066\u3001\u6bce\u65e5\u3000\u6700\u7d42\u30bb\u30c3\u30b7\u30e7\u30f3\u3067\u30dd\u30b9\u30bf\u30fc\u8b1b\u6f14\u304c\u958b\u50ac\u3055\u308c\u305f\u3002<br \/>\n\u4f1a\u5834\u306f\u5c11\u3057\u72ed\u304b\u3063\u305f\u304b\u306a\u3002<br \/>\n\u3010\u304a\u308f\u308a\u306b\u3011<br \/>\n&nbsp;<br \/>\n&#8212;-<br \/>\n<strong>\u5b66\u4f1a\u53c2\u52a0\u5831\u544a\u66f8<\/strong><\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"147\"><strong>\u00a0<\/strong><strong>\u5831\u544a\u8005\u6c0f\u540d<\/strong><\/td>\n<td width=\"373\">\u8429\u539f\u91cc\u5948<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u767a\u8868\u8ad6\u6587\u30bf\u30a4\u30c8\u30eb<\/strong><\/td>\n<td width=\"373\">Functional connectivity analysis of working memory during a mental arithmetic task<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u767a\u8868\u8ad6\u6587\u82f1\u30bf\u30a4\u30c8\u30eb<\/strong><\/td>\n<td width=\"373\">Functional connectivity analysis of working memory during a mental arithmetic task<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u8457\u8005<\/strong><\/td>\n<td width=\"373\">\u8429\u539f\u91cc\u5948\uff0c\u65e5\u548c\u609f\uff0c\u5ee3\u5b89\u77e5\u4e4b<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u4e3b\u50ac<\/strong><\/td>\n<td width=\"373\">The Intermational Neuroinformatics Coordinating Facility<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u8b1b\u6f14\u4f1a\u540d<\/strong><\/td>\n<td width=\"373\">Neuroinformatics2016<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u4f1a\u5834<\/strong><\/td>\n<td width=\"373\">Meadow Suite at Reading University<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u958b\u50ac\u65e5\u7a0b<\/strong><\/td>\n<td width=\"373\">2016\/9\/3-2016\/9\/4<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<br \/>\n&nbsp;<\/p>\n<ol>\n<li>\u8b1b\u6f14\u4f1a\u306e\u8a73\u7d30<\/li>\n<\/ol>\n<p>2016\/9\/3-4\u306b\uff0c\u30a4\u30ae\u30ea\u30b9\u306e\u30ec\u30c7\u30a3\u30f3\u30b0\u306b\u3066\u958b\u50ac\u3055\u308c\u307e\u3057\u305fNeuroinformatics\u306b\u53c2\u52a0\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u3053\u306e\u5927\u4f1a\u306f\uff0cThe Intermational Neuroinformatics Coordinating Facility\u306b\u3088\u3063\u3066\u4e3b\u50ac\u3055\u308c\u305f\u5927\u4f1a\u3067\uff0c\u30c7\u30fc\u30bf\u3084\u77e5\u8b58\u30d9\u30fc\u30b9\u306e\u795e\u7d4c\u30b7\u30b9\u30c6\u30e0\uff0c\u795e\u7d4c\u30b7\u30b9\u30c6\u30e0\u30c7\u30fc\u30bf\u306e\u305f\u3081\u306e\u30c4\u30fc\u30eb\uff0c\u8133\u306e\u30e2\u30c7\u30eb\u5316\u306b\u95a2\u3059\u308b\u5e45\u5e83\u3044neuroinformatics\u306b\u643a\u308f\u308b\u53c2\u52a0\u8005\u304c\u96c6\u307e\u308a\uff0c\u795e\u7d4c\u79d1\u5b66\u306e\u30c4\u30fc\u30eb\u306e\u958b\u767a\uff0c\u795e\u7d4c\u79d1\u5b66\u30c7\u30fc\u30bf\u306e\u51e6\u7406\u65b9\u6cd5\u306b\u3064\u3044\u3066\u8b70\u8ad6\u3059\u308b\u3053\u3068\u3092\u76ee\u7684\u306b\u958b\u50ac\u3055\u308c\u3066\u3044\u307e\u3059\uff0e<br \/>\n\u672c\u7814\u7a76\u5ba4\u304b\u3089\u306f\u4ed6\u306b\u5ee3\u5b89\u5148\u751f\uff0c\u65e5\u548c\u5148\u751f\uff0cM1\u306e\u5409\u6b66\u3055\u3093\uff0c\u7389\u57ce\u3055\u3093\u304c\u53c2\u52a0\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ol start=\"2\">\n<li>\u7814\u7a76\u767a\u8868\n<ul>\n<li>\u767a\u8868\u6982\u8981<\/li>\n<\/ul>\n<\/li>\n<\/ol>\n<p>\u79c1\u306f3\u65e5\u306e\u30dd\u30b9\u30bf\u30fc\u30bb\u30c3\u30b7\u30e7\u30f3\u306b\u53c2\u52a0\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u767a\u8868\u306e\u5f62\u5f0f\u306f\u30dd\u30b9\u30bf\u30fc\u767a\u8868\u3067\uff0c2\u6642\u9593\u81ea\u7531\u306b\u53c2\u52a0\u8005\u306e\u65b9\u3068\u8b70\u8ad6\u3092\u884c\u3044\u307e\u3057\u305f\uff0e<br \/>\n\u4eca\u56de\u306e\u767a\u8868\u306f\uff0c\u300cFunctional connectivity analysis of working memory during a mental arithmetic task\u300d\u3068\u984c\u3057\u3066\u767a\u8868\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u4ee5\u4e0b\u306b\u6284\u9332\u3092\u8a18\u8f09\u3057\u307e\u3059\uff0e<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\"><strong>Introduction: <\/strong>We spend daily life by using a storage system called working memory. Working memory (WM) has been defined as a system for the temporary holding and manipulation of the information (Baddeley and Hitch, 1974; Baddeley, 2000). It plays an important role in cognitive functions such as language recognition and reasoning ability. A limited memory buffer of retaining and processing the information is called as working memory capacity (WMC), and it is different between individuals. The individual differences in WMC affect a variety of cognitive activities. For example, poor WMC is said to be related to attention deficit hyperactivity disorder (ADHD), and working memory training to make WMC increased is used as treatment for ADHD patients (Klingberg et al., 2002). Working memory is used in the case of reading and solving mental arithmetic. Reading span test and N-back task are often used as an assessment of WMC. However, these paradigms are far from our daily life. Therefore, in this study, we adopted mental arithmetic task often used in everyday life. In a complex system such as working memory, each brain region does not always activate individually but often works cooperatively with other regions. Although the brain regions associated with working memory during mental arithmetic task had been revealed (Fehr et al., 2007), cooperative relationship among these regions have not been investigated enough. Therefore, in this study, we investigated the cooperative relationship among the brain regions during mental arithmetic task using a functional connectivity magnetic resonance imaging (fcMRI) study.<strong>Materials and Methods: <\/strong>Fourteen healthy adults (average age: 22.5 \u00b1 1.5 years, 13 right-handed, 11 male) participated in this study. Participants performed the mental arithmetic task, which was consisted of the easy (non-working memory) and difficult (working memory) task, in the fMRI scanner. We calculated the correlation matrix and analyzed the functional connectivity. Acquired images were preprocessed by SPM8, and the activated regions were extracted and analyzed. A functional connectivity matrix of the individual data was calculated using Conn toolbox (Susan and Nieto-Castanon, 2012). Each image was partitioned into 116 regions using automatic anatomical labeling\u3000(AAL) atlas, and ROI-to-ROI connectivity was calculated for 116 regions. Moreover, graph theory metrics (degree and clustering coefficient) were calculated for each functional connectivity matrix using Brain Connectivity Toolbox (Mikail and Sporns, 2010). Degree is the number of edges connected to other nodes and indicates the centrality of a certain node (the brain region). Clustering coefficient indicates the degree to which nodes tend to cluster together. Moreover, the community of the brain network is extracted using Newman algorithm, which is a graph partitioning method for network analysis. These metrics allow us to quantitatively analyze the structure of brain network.<strong>Results and Discussions: <\/strong>Average correct answers of easy and difficult tasks were 30.7 \u00b1 4.9 and 3.88 \u00b1 1.17%, respectively, and it was confirmed that the answers of easy task were significantly higher than those of difficult task [<em>t <\/em>(13) = 22.5, <em>p <\/em>&lt; 0.01). By group analysis, we performed a paired <em>t<\/em>-test to examine the difference of activation between easy task and difficult task. Supplementary motor area and middle temporal gyrus were extracted as the regions whose activations were significantly higher for difficult task than for easy task. Significant activated regions during the difficult task were both cuneus and left precuneus. Since these regions are associated with working memory (Tomasi et al., 2006; Neta and Whalen, 2011; Sala-Llonch et al., 2012), they activated during the difficult task. Moreover, degree measures of these regions were significantly higher for difficult task than for easy task (paired <em>t<\/em>-test, <em>p <\/em>&lt; 0.05). This suggested that these regions worked cooperatively with other regions during the difficult task compared with during the easy task. On the other hand, the clustering coefficient is higher for difficult task than for easy task for all regions (<em>p <\/em>&lt; 0.05). This indicated that brain regions tended to form a cluster during the difficult task. Furthermore, 116 brain regions were partitioned into four communities, the frontal lobe, the parietal lobe, the temporal lobe and the occipital lobe in easy task. In difficult task, the frontal lobe and the parietal lobe were categorized into the same group, so that three communities were identified. These results suggested that the frontal lobe and the parietal lobe needed to work together during working memory task. In addition, observation of the regions connected from the both cuneus revealed that there were connections from the both cuneus to the frontal lobe (left middle frontal gyrus) and the parietal lobe (left inferior parietal lobule, left paracentral lobule) during difficult task. The frontal\u2013parietal network is associated with visual attention, and controls the occipital visual cortex to selectively process only the required visual information (Nobre et al., 1997). Since our results found connections between the both cuneus and the frontal and parietal lobes, it suggested that the cuneus (the occipital visual cortex) was controlled by the frontal lobe and the parietal lobe.<br \/>\n&nbsp;<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<\/p>\n<ul>\n<li>\u8cea\u7591\u5fdc\u7b54<\/li>\n<\/ul>\n<p>\u4eca\u56de\u306e\u8b1b\u6f14\u767a\u8868\u3067\u306f\uff0c\u4ee5\u4e0b\u306e\u3088\u3046\u306a\u8cea\u7591\u3092\u53d7\u3051\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>1<\/strong><br \/>\n\u8cea\u554f\u8005\u306e\u6c0f\u540d\u3092\u63a7\u3048\u640d\u306d\u3066\u3057\u307e\u3044\u307e\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306f\u76f8\u95a2\u884c\u5217\u306e\u95be\u5024\u306f\u3044\u304f\u3064\u3067\uff0c\u30a8\u30c3\u30b8\u306e\u5024\u306f\u30d0\u30a4\u30ca\u30ea\u3067\u3042\u308b\u304b\u3068\u3044\u3046\u3082\u306e\u3067\u3057\u305f\uff0e\u95be\u5024\u306f0\u3068\u3057\uff0cnegative connectivity\u306f\u691c\u8a0e\u305b\u305a\uff0cpositive connectivity\u306e\u307f\u307f\u3066\u304a\u308a\uff0c\u30a8\u30c3\u30b8\u306f\u76f8\u95a2\u4fc2\u6570\u306e\u91cd\u307f\u304c\u3042\u308b\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>2<\/strong><br \/>\n\u8cea\u554f\u8005\u306e\u6c0f\u540d\u3092\u63a7\u3048\u640d\u306d\u3066\u3057\u307e\u3044\u307e\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306f\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306f\u5b9f\u9a13\u8a2d\u8a08\u5168\u4f53\u306e\u6642\u7cfb\u5217\u30c7\u30fc\u30bf\u3092\u7528\u3044\u3066\u3044\u308b\u306e\u304b\uff0c\u3042\u308b\u3044\u306f\u30bf\u30b9\u30af\u306e\u6642\u7cfb\u5217\u30c7\u30fc\u30bf\u306e\u307f\u7528\u3044\u3066\u3044\u308b\u306e\u304b\u3068\u3044\u3046\u3082\u306e\u3067\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306b\u5bfe\u3059\u308b\u56de\u7b54\u3067\u3059\u304c\uff0c\u5404\u30bf\u30b9\u30af\u306e\u6642\u7cfb\u5217\u30c7\u30fc\u30bf\u3092\u62bd\u51fa\u3057\u9023\u7d50\u3057\u3066\u3044\u308b\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>3<\/strong><br \/>\n<strong>\u3000<\/strong>\u8cea\u554f\u8005\u306e\u6c0f\u540d\u3092\u63a7\u3048\u640d\u306d\u3066\u3057\u307e\u3044\u307e\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306f\uff0c\u30cd\u30c3\u30c8\u30ef\u30fc\u30af\u7279\u5fb4\u91cf\u306fStrength\u306e\u307f\u3092\u7528\u3044\u3066\u3044\u308b\u304b\u3068\u3044\u3046\u3082\u306e\u3067\u3057\u305f\uff0e\u3053\u306e\u8cea\u554f\u306b\u5bfe\u3057\u3066\uff0c\u4eca\u56de\u306fStrength\u306e\u307f\u306e\u691c\u8a0e\u3067\u3042\u308a\uff0c\u4eca\u5f8cClustering coefficient\u3084Modularity\u306a\u3069\u306e\u7279\u5fb4\u91cf\u3082\u691c\u8a0e\u3057\u3066\u3044\u304d\u305f\u3044\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>4<\/strong><br \/>\n\u682a\u5f0f\u4f1a\u793e\u30c9\u30ef\u30f3\u30b4\u6240\u5c5e\u306e\u5c71\u5ddd\u3055\u3093\u304b\u3089\u306e\u8cea\u554f\u3067\u3059\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306f\uff0c\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306e\u9055\u3044\u306fStrength\u3092\u691c\u8a0e\u3059\u308b\u524d\u306b\uff0c\u76f4\u63a5\u7684\u306b\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306e\u9055\u3044\u3092\u691c\u8a0e\u3057\u3066\u3044\u306a\u3044\u306e\u304b\u3068\u3044\u3046\u3082\u306e\u3067\u3057\u305f\uff0e\u307e\u305f\uff0c\u4eca\u56de\u306e\u7d50\u679c\u306e\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306e\u9055\u3044\u306f\u5148\u884c\u7814\u7a76\u3067\u793a\u3055\u308c\u3066\u3044\u308b\u304b\u3068\u3044\u3046\u8cea\u554f\u3092\u3044\u305f\u3060\u304d\u307e\u3057\u305f\uff0e\u4eca\u56de\u306f\uff0c\u76f4\u63a5\u7684\u306a\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306e\u6bd4\u8f03\u306f\u76ee\u8996\u306e\u307f\u3067\u884c\u3063\u3066\u3044\u308b\u305f\u3081\uff0c\u4eca\u5f8c\u691c\u8a0e\u3057\u305f\u3044\u3068\u601d\u3046\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e\u307e\u305f\uff0c\u62bd\u51fa\u3055\u308c\u305f\u8133\u9818\u57df\u306e\u6a5f\u80fd\u306b\u95a2\u3057\u3066\u306e\u307f\u5148\u884c\u7814\u7a76\u3067\u8abf\u3079\u304c\uff0c\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306b\u95a2\u3059\u308b\u5148\u884c\u7814\u7a76\u306f\u8abf\u3079\u3089\u308c\u3066\u3044\u306a\u3044\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e\u4eca\u5f8c\u691c\u8a0e\u3057\u305f\u3044\u3068\u601d\u3044\u307e\u3059\uff0e<br \/>\n&nbsp;<\/p>\n<ul>\n<li>\u611f\u60f3<\/li>\n<\/ul>\n<p>2\u5ea6\u76ee\u306e\u5b66\u4f1a\u767a\u8868\u3067\u3057\u305f\u304c\uff0c\u4eca\u56de\u306f\u521d\u3081\u3066\u306e\u56fd\u969b\u5b66\u4f1a\u3067\u3042\u308a\uff0c\u521d\u3081\u3066\u306e\u30dd\u30b9\u30bf\u30fc\u767a\u8868\u3067\u3042\u3063\u305f\u305f\u3081\uff0c\u3068\u3066\u3082\u7dca\u5f35\u3057\u307e\u3057\u305f\uff0e\u65e5\u548c\u5148\u751f\u306e\u3054\u6307\u5c0e\u306e\u304a\u304b\u3052\u3067\uff0c\u30a4\u30f3\u30d1\u30af\u30c8\u306e\u3042\u308b\u30dd\u30b9\u30bf\u30fc\u3092\u4f5c\u6210\u3059\u308b\u3053\u3068\u304c\u3067\u304d\u305f\u305f\u3081\uff0c\u591a\u304f\u306e\u65b9\u306b\u30dd\u30b9\u30bf\u30fc\u3092\u307f\u3066\u3044\u305f\u3060\u304f\u3053\u3068\u304c\u3067\u304d\u307e\u3057\u305f\uff0e \u3069\u306e\u65b9\u3082\u3068\u3066\u3082\u512a\u3057\u304f\uff0c\u305f\u3069\u305f\u3069\u3057\u3044\u82f1\u8a9e\u3067\u3057\u305f\u304c\uff0c\u306a\u3093\u3068\u304b\u81ea\u5206\u306e\u7814\u7a76\u3092\u82f1\u8a9e\u3067\u4f1d\u3048\u308b\u3053\u3068\u304c\u3067\u304d\u305f\u306e\u3067\u306f\u306a\u3044\u304b\u3068\u601d\u3044\u307e\u3059\uff0e\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u306e\u7814\u7a76\u3084\uff0c\u30b0\u30e9\u30d5\u7406\u8ad6\u3092\u7528\u3044\u305f\u7814\u7a76\u3082\u591a\u304f\u3042\u308a\uff0c\u81ea\u5206\u306e\u77e5\u8b58\u304c\u4e0d\u5341\u5206\u3067\u3042\u308b\u3053\u3068\u3092\u611f\u3058\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ol start=\"3\">\n<li>\u8074\u8b1b<\/li>\n<\/ol>\n<p>\u4eca\u56de\u306e\u8b1b\u6f14\u4f1a\u3067\u306f\uff0c\u4e0b\u8a18\u306e2\u4ef6\u306e\u767a\u8868\u3092\u8074\u8b1b\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">\u767a\u8868\u30bf\u30a4\u30c8\u30eb\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a\u3000Whole brain fMRI activity at a high temporal resolution: A novel analytic framework\u8457\u8005\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Niels Janssen\u30bb\u30c3\u30b7\u30e7\u30f3\u540d\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Track C &#8211; Neuroimaging I<br \/>\nAbstruct\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a<br \/>\nWe have developed a new framework for the analysis of functional Magnetic Resonance Imaging (fMRI) data. Whereas current analytic techniques primarily yield static, time-invariant maps of fMRI activity (Smith et al., 2004), our new technique yields dynamic, time-variant videos of whole-brain fMRI activity. The new framework relies on a fundamentally different method of fMRI BOLD signal extraction. Specifically, instead of the standard volume-based signal extraction, the new method extracts the fMRI BOLD signal based on the veridical MRI slice acquisition times. This yields an fMRI signal that is more temporally accurate (Sladky et al., 2011). In addition, we improved the temporal resolution by presenting each slice to a different point in the progression of the BOLD signal [see also Price et al. (1999)]. The fMRI BOLD signal is then extracted using non-standard statistical modeling techniques. Specifically, the fMRI data are first broken up into epochs that are time-locked to the onset of a stimulus. Next, in line with techniques used in EEG (Janssen et al., 2014), statistical models are run at each time-point in the epoch. As the baseline, we used the fMRI signal intensity values available at time-point 0. For this particular choice of baseline, modeling involves extracting the fMRI BOLD signal across time points in the epoch. The number of available timepoints in the epoch (and therefore the temporal resolution) is scalable, up to a maximum that is determined by the rate at which MRI slices are acquired (typically on the order of tens of milliseconds). In order to account for the full complexity of the statistical model, we used Linear Mixed Effect modeling (Pinheiro and Bates, 2000). Our method yields an fMRI signal for every voxel in the brain that is more temporally accurate and of a much higher temporal resolution that is available in current frameworks.<br \/>\nThe data manipulation in the new framework relies on functions written as part of the neuro-imaging data analysis package FSL (Smith et al., 2004) and various Python scripts of which the NiBabel package for reading neuro-imaging data forms an indispensable part (http:\/\/nipy.org\/nibabel\/). Statistical modeling of first order individual participant data relied on the data.table and lme4 packages available in the software R (Douglas et al., 2015). Higher order modeling was performed with the randomise function of FSL (Winkler et al., 2014). A key characteristic of the current approach is that it does not rely on data averaging but uses all data points from all epochs in an experiment to model the signal. Advantages of using this pipeline are that statistical modeling of first-order fMRI data is greatly simplified and handled by R. Disadvantages are the slow speed of R, and the large file sizes due to the long data table format requirements imposed by R. We will illustrate the new technique in the context of fMRI data collected during a visual object naming experiment. We will use these data to explore the spatio-temporal dynamics of the whole-brain fMRI BOLD signal at 390 ms temporal resolution, focusing on task-based functional connectivity. Our new framework can be easily applied to data collected with other types of tasks and provides a novel opportunity to gain insight into the spatio-temporal dynamics of fMRI activity during cognitive tasks.<br \/>\n&nbsp;<br \/>\n<strong>Acknowledgment<\/strong><br \/>\nThis work was supported by The Spanish Ministry of Economy and Competitiveness (RYC2011-08433 and PSI2013-46334 to NJ)<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>fMRI\u306e\u64ae\u50cf\u6642\u9593\u306b\u95a2\u3059\u308b\u554f\u984c\u306b\u95a2\u3059\u308b\u767a\u8868\u3067\u3057\u305f\uff0e1\u30dc\u30ea\u30e5\u30fc\u30e0\u3067\u30b9\u30e9\u30a4\u30b9\u6bce\u306b\u6642\u9593\u304c\u9055\u3046\u3053\u3068\u30681\u30dc\u30ea\u30e5\u30fc\u30e0\u6bce\u306e\u6642\u9593\u5206\u89e3\u80fd\u304c\u4f4e\u3044\u3053\u3068\u306e\u4e21\u65b9\u306b\u95a2\u3057\u3066\u30a2\u30d7\u30ed\u30fc\u30c1\u3059\u308b\u3082\u306e\uff0cSlice-Based\u624b\u6cd5\u306b\u3088\u308a\u540c\u3058\u30bf\u30a4\u30df\u30f3\u30b0\u306e\u30b9\u30e9\u30a4\u30b9\u30671\u30dc\u30ea\u30e5\u30fc\u30e0\u3092\u64ae\u50cf\u3059\u308b\u3082\u306e\u3067\u3057\u305f\uff0e\u5b9f\u9a13\u3067\u7528\u3044\u3066\u3044\u308bMRI\u306e\u6642\u9593\u5206\u89e3\u306f\u9ad8\u304f\u306a\u3044\u305f\u3081\uff0c\u89e3\u6790\u306e\u969b\u306b\u306f\u30b9\u30e9\u30a4\u30b9\u30bf\u30a4\u30df\u30f3\u30b0\u306b\u3064\u3044\u3066\u3082\u8003\u3048\u308b\u5fc5\u8981\u304c\u3042\u308b\u3068\u518d\u78ba\u8a8d\u3055\u305b\u3089\u308c\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">\u767a\u8868\u30bf\u30a4\u30c8\u30eb\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a\u3000Measuring complex brain networks structure\u8457\u8005\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Ester Bonmati, Anton Bardera, Imma Boada\u30bb\u30c3\u30b7\u30e7\u30f3\u540d\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Track E &#8211; Informatics III: Visualization<br \/>\nAbstruct\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a<br \/>\n<strong>Introduction: <\/strong>The human brain has roughly one hundred billion neurons forming a network with trillions of intra-connections. The mapping of structure and functionality of brain networks is therefore an important challenge in understanding the functioning. Connectivity matrices are used to represent brain networks, also called connectome (Hagmann, 2005; Sporns et al., 2005), as a graph (Hagmann et al., 2007, 2010; Sporns, 2013), where nodes correspond to brain regions and edges to structural or functional connections (Bullmore and Bassett, 2011; Sporns, 2011; Wu et al., 2013).<br \/>\nDifferent measures have been applied to describe topological features of brain networks (Stam and Reijneveld, 2007; Rubinov and Sporns, 2010; Kaiser, 2011). For instance, the independence of large areas, denoted as integration, has been studied by the path length measure, the characteristic path length (Watts and Strogatz, 1998), or the global efficiency (Latora and Marchiori, 2001). Independence of small subsets, defined as segregation, can be analyzed by the clustering coefficient (Watts and Strogatz, 1998), the transitivity (Newman, 2003a), or the modularity (Newman, 2003b). The importance of individual nodes can be defined with centrality measures such as the degree (Bullmore and Sporns, 2009). A good summary of the measures can be found in Rubinov and Sporns (2010).<br \/>\nIn this work, we present a global and two local measures, based on the mutual information measure, to quantify brain networks structure.<br \/>\n<strong>Materials and Methods: <\/strong><em>Materials<\/em>: Synthetic model networks were created using the Brain Connectivity Toolbox (BCT) (Rubinov and Sporns, 2010). Random, lattice, ring lattice, and small-world model networks with 128 and 256 nodes with edges ranging from 128 to 8192 with a step of 128 edges were used. Additionally, networks with nodes ranging from 32 to 512 with a step of 32 and a density of 0.4 were also created.<br \/>\nAs human structural networks, we used the normalized connection matrices created from MRI tractography described in Cammoun et al. (2012). As human functional networks, we used the HCP 500-PTN functional dataset (Van Essen et al., 2012; Glasser et al., 2013; Hodge et al., 2015).<br \/>\nAll networks were weighted and non-directed.<br \/>\n<em>Method<\/em>: In the proposed approach, brain networks are modelled as a Markov process where neuronal impulses randomly walk from one node to another node. This new interpretation provides a solid theoretical framework from which we derive a global (i.e., a single value for the whole network) and two local (i.e., a value for each node) measures based on mutual information.<br \/>\nMutual information (MI) measures the shared information between two random variables. From our Markov process-based brain model, we propose as a global connectivity measure the mutual information between two consecutive states of the process. Mutual information can also be seen as the difference between the uncertainty of the states without any knowledge and the uncertainty of the states when the past is known (or information gained when the previous node is known). The higher the MI, the less random the connections. Thus, mutual information can be used to quantify the overall brain structure.<br \/>\nThe mutual information can be decomposed in order to characterize the degree of informativeness of each state. When applied to the connectome, since each state corresponds to an anatomical or functional region, this measure can be seen as the contribution of each node to the whole graph structure. In this work, we propose two local measures. On the one hand, we use the mutual surprise (I1) (DeWeese and Meister, 1999), that expresses how \u201csurprising\u201d are the connections of a node. Nodes that are connected with more likely nodes will lead to low values of mutual surprise, while those with very specific connections or connected with few unlikely nodes will have high mutual surprise. On the other hand, we use the mutual predictability (I2) (DeWeese and Meister, 1999), that expresses the uncertainty of a node taking into account the mean connectivity of all the network. I2 measures the capacity of prediction for a given brain region.<br \/>\n<strong>Results and Discussion: <\/strong>Using model networks with different number of edges, an optimum point was found for lattice and ring lattice networks when increasing the density. This is due to the fact that for low densities, there are regions not connected, thus, the overall mutual information is low. This fact may help to find a minimum number of fibers needed to study brain networks for a given brain parcellation. Overall, higher values were obtained for lattice and ring lattice models, showing a clear evidence of more organized networks compared with random and small-world networks. When the number of edges was increased, the mutual information tended to decrease, since the higher number of connections, the lower correlation between consecutive states. Preserving the density, the mutual information was not very sensitive to random and small-world networks, since the structure is similar. Higher values were obtained for ring lattice networks when comparing with lattice networks, since in lattice networks two nodes are not connected and have a less structured network. Using anatomical and functional connectomes at different scales, a similar behavior was observed for all patients.<br \/>\nLocal measures were evaluated using the human connectomes. The mutual surprise highlighted regions connected to regions not highly connected, such as the right hemisphere transverse temporal. Low values were obtained for regions connected to highly connected regions such as the left hemisphere thalamus proper. The mutual predictability associated regions with a low number of connections and high weights with a high predictability, such us the right hemisphere temporal pole. Low values were obtained in regions with more uncertainly in predicting the next node, such as the right hemisphere putamen.<br \/>\nAll measures were consistent for structural and functional human networks.<br \/>\n<strong>Conclusion: <\/strong>In this work, new measures to quantify structure of complex brain networks are proposed. Brain connectivity graphs are interpreted as a stochastic process where neural impulses are modeled as a random walk. This interpretation provides a solid theoretical framework from which different measures based on the mutual information measure have been applied.<br \/>\nThe measures have been tested on synthetic model networks and structural and functional human networks at different scales. Results show that the mutual information is able to quantify the structure of different model networks. The mutual surprise, allows the identification of nodes whose neighbors have a high connectivity taking into account all connections. The mutual predictability shows that regions with a high clustering tend to be more predictable.<br \/>\n<strong>Acknowledgments<\/strong><br \/>\nThis work was supported by the Spanish Government (Grant No. TIN2013-47276-<br \/>\nC6-1-R) and by the Catalan Government (Grant No. 2014-SGR-1232). Data were provided, in part, by the Human Connectome Project, WU-Minn Consortium (Principal Investigators: David Van Essen and Kamil Ugurbil; 1U54MH091657) funded by the 16 NIH Institutes and Centers that support the NIH Blueprint for Neuroscience Research; and by the McDonnell Center for Systems Neuroscience at Washington University.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>\u672c\u767a\u8868\u306f\uff0c\u69cb\u9020\u7684\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u3092\u30b0\u30e9\u30d5\u7406\u8ad6\u3092\u7528\u3044\u3066\u89e3\u6790\u3059\u308b\u3082\u306e\u3067\u3057\u305f\uff0e\u79c1\u306f\u6a5f\u80fd\u7684\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u3092\u30b0\u30e9\u30d5\u7406\u8ad6\u306b\u3088\u3063\u3066\u89e3\u6790\u3057\u3066\u3044\u308b\u306e\u3067\uff0c\u95a2\u9023\u3059\u308b\u767a\u8868\u3067\u3057\u305f\u304c\uff0c\u30de\u30eb\u30b3\u30d5\u9023\u9396\u3092\u7528\u3044\u308b\u3053\u3068\u3067\u8133\u306e\u72b6\u614b\u3092\u691c\u8a0e\u3057\u3066\u3044\u307e\u3057\u305f\uff0e\u30b0\u30e9\u30d5\u7406\u8ad6\u3060\u3051\u3067\u306a\u304f\u4ed6\u306e\u89e3\u6790\u65b9\u6cd5\u3092\u7528\u3044\u308b\u3053\u3068\u3067\uff0c\u3088\u308a\u6df1\u3044\u7814\u7a76\u3092\u884c\u3063\u3066\u3044\u304d\u305f\u3044\u3068\u611f\u3058\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n\u53c2\u8003\u6587\u732e<\/p>\n<ul>\n<li>Neuroinformatics 2016,<\/li>\n<\/ul>\n<p>http:\/\/neuroinformatics2016.org\/<br \/>\n&nbsp;<br \/>\n<strong>\u5b66\u4f1a\u53c2\u52a0\u5831\u544a\u66f8<\/strong><\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"147\"><strong>\u5831\u544a\u8005\u6c0f\u540d<\/strong><\/td>\n<td width=\"373\">\u7389\u57ce\u8cb4\u4e5f<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u767a\u8868\u8ad6\u6587\u30bf\u30a4\u30c8\u30eb<\/strong><\/td>\n<td width=\"373\">Region-of-interest estimation using convolutional neural\u00a0network and long short-term memory for functional\u00a0near-infrared spectroscopy data<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u767a\u8868\u8ad6\u6587\u82f1\u30bf\u30a4\u30c8\u30eb<\/strong><\/td>\n<td width=\"373\">Region-of-interest estimation using convolutional neural<br \/>\nnetwork and long short-term memory for functional<br \/>\nnear-infrared spectroscopy data<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u8457\u8005<\/strong><\/td>\n<td width=\"373\">\u7389\u57ce\u8cb4\u4e5f\uff0c\u65e5\u548c\u609f\uff0c\u8702\u9808\u8cc0\u5553\u4ecb\uff0c\u5965\u91ce\u82f1\u4e00\uff0c\u5ee3\u5b89\u77e5\u4e4b<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u4e3b\u50ac<\/strong><\/td>\n<td width=\"373\">The Intermational Neuroinformatics Coordinating Facility<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u8b1b\u6f14\u4f1a\u540d<\/strong><\/td>\n<td width=\"373\">Neuroinformatics2016<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u4f1a\u5834<\/strong><\/td>\n<td width=\"373\">Meadow Suite at Reading University<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u958b\u50ac\u65e5\u7a0b<\/strong><\/td>\n<td width=\"373\">2016\/9\/3-2016\/9\/4<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<br \/>\n&nbsp;<\/p>\n<ol>\n<li>\u8b1b\u6f14\u4f1a\u306e\u8a73\u7d30<\/li>\n<\/ol>\n<p>2016\/9\/3-4\u306b\uff0c\u30a4\u30ae\u30ea\u30b9\u306e\u30ec\u30c7\u30a3\u30f3\u30b0\u306b\u3066\u958b\u50ac\u3055\u308c\u307e\u3057\u305fNeuroinformatics\u306b\u53c2\u52a0\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u3053\u306e\u5927\u4f1a\u306f\uff0cThe Intermational Neuroinformatics Coordinating Facility\u306b\u3088\u3063\u3066\u4e3b\u50ac\u3055\u308c\u305f\u5927\u4f1a\u3067\uff0c\u30c7\u30fc\u30bf\u3084\u77e5\u8b58\u30d9\u30fc\u30b9\u306e\u795e\u7d4c\u30b7\u30b9\u30c6\u30e0\uff0c\u795e\u7d4c\u30b7\u30b9\u30c6\u30e0\u30c7\u30fc\u30bf\u306e\u305f\u3081\u306e\u30c4\u30fc\u30eb\uff0c\u8133\u306e\u30e2\u30c7\u30eb\u5316\u306b\u95a2\u3059\u308b\u5e45\u5e83\u3044neuroinformatics\u306b\u643a\u308f\u308b\u53c2\u52a0\u8005\u304c\u96c6\u307e\u308a\uff0c\u795e\u7d4c\u79d1\u5b66\u306e\u30c4\u30fc\u30eb\u306e\u958b\u767a\uff0c\u795e\u7d4c\u79d1\u5b66\u30c7\u30fc\u30bf\u306e\u51e6\u7406\u65b9\u6cd5\u306b\u3064\u3044\u3066\u8b70\u8ad6\u3059\u308b\u3053\u3068\u3092\u76ee\u7684\u306b\u958b\u50ac\u3055\u308c\u3066\u3044\u307e\u3059\uff0e<br \/>\n\u672c\u7814\u7a76\u5ba4\u304b\u3089\u306f\u4ed6\u306b\u5ee3\u5b89\u5148\u751f\uff0c\u65e5\u548c\u5148\u751f\uff0cM1\u306e\u5409\u6b66\u3055\u3093\uff0c\u8429\u539f\u3055\u3093\u304c\u53c2\u52a0\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ol start=\"2\">\n<li>\u7814\u7a76\u767a\u8868\n<ul>\n<li>\u767a\u8868\u6982\u8981<\/li>\n<\/ul>\n<\/li>\n<\/ol>\n<p>\u79c1\u306f3\u65e5\u306e\u30dd\u30b9\u30bf\u30fc\u30bb\u30c3\u30b7\u30e7\u30f3\u306b\u53c2\u52a0\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u767a\u8868\u306e\u5f62\u5f0f\u306f\u30dd\u30b9\u30bf\u30fc\u767a\u8868\u3067\uff0c2\u6642\u9593\u81ea\u7531\u306b\u53c2\u52a0\u8005\u306e\u65b9\u3068\u8b70\u8ad6\u3092\u884c\u3044\u307e\u3057\u305f\uff0e<br \/>\n\u4eca\u56de\u306e\u767a\u8868\u306f\uff0c\u300cRegion-of-interest estimation using convolutional neural network and long short-term memory for functional near-infrared spectroscopy data\u300d\u3068\u984c\u3057\u3066\u767a\u8868\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u4ee5\u4e0b\u306b\u6284\u9332\u3092\u8a18\u8f09\u3057\u307e\u3059\uff0e<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\"><strong>Introduction<\/strong>: In recent years, functional near-infrared spectroscopy (fNIRS) has attracted attention as a noninvasive functional neuroimaging technology. fNIRS visualizes brain activity by measuring the hemodynamic responses of oxy- and deoxyhemoglobin (Hb) associated with neural behavior. fNIRS allows us to identify a cortical activation or brain regions associated with a given stimulus by analyzing the time courses of oxy- and deoxy-Hb. However, since fNIRS signals often contain noises (e.g., motion-related artifacts and psychological noises including heartbeat), it is not easy to extract meaningful brain activation. Furthermore, comparison of the raw fNIRS data between subjects should not be done because fNIRS detects only the relative change in oxy- or deoxy-Hb. To perform a group analysis, baseline calibration is also needed. However, there is no established way for preprocessing of fNIRS signals. The purpose of this study was to estimate the brain regions associated with a given task or stimulus by automatically extracting features of cortical activities from the fNIRS data. We proposed a novel feature extraction method for the fNIRS signals whose temporal and spatial characteristics were considered.<br \/>\n<strong>Method<\/strong>: Deep learning methods have been mostly used for classification of multi-dimensional data, however, in this study, we focused on another aspect of the deep learning methodology regarding determination of region-of-interest (ROI) associated with a given task or stimuli. In our proposed approach, a group classifier is constructed from all subject fNIRS data using supervised learning. The group classifier is constructed for all channels of a fNIRS measurement system, and a group label is supervised during each learning process. After the learning is completed, the classification accuracy using only a single channelis compared among all channels, and the channel whose classification accuracy hasbetter performance is extracted as the critical ROI for group classification.Moreover, we proposed a new deep learning algorithm which is a fusion of two algorithms,convolutional neural network (CNN) (LeCun, 1998) and long short-termmemory (LSTM) (Hochreiter and Schmidhuber, 1997). Although both algorithmscan automatically perform feature extraction, CNN preserves the spatial informationon input data during learning, and LSTM stores the temporal information. Takingadvantage of these two algorithms, our proposed algorithm basically consisted of fivelayers, input, convolution, LSTM, pooling, and output layer. We can identify the ROIbecause neuron units of the input layer are associated with the fNIRS probes placedon participants\u2019 head.<br \/>\n<strong>Experiments<\/strong>: To examine the effectiveness of our approach, we tried to extract theROIs related to working memory. Cerebral blood flow during N-back (N = 2, 3) task,which was often used to assess the working memory, was measured using fNIRS. 30healthy male subjects (average age: 23.3 \u00b1 1.5 years, right-handed) and 5 healthy femalesubjects (average age: 21.7 \u00b1 0.52 years, right-handed) participated in the experiment.The fNIRS probes were placed according to the International 10\u201320 system. Usingthe fNIRS data obtained, our classifier is trained to classify the input data as either\u201c2-back\u201d or \u201c3-back.\u201d<br \/>\n<strong>Results and Discussion<\/strong>: The average percentage of correct answers in 2-back (low degree of difficulty) and 3-back (high degree of difficulty) tasks were 90.2 \u00b1 8.98 and 84.3\u00a0 \u00b1\u00a0 8.87%, respectively. It was shown to be significantly different by Wilcoxon signed-rank test (p &lt; 0.01). Using this fNIRS data, our classifier achieved the classification accuracy of 91.4 \u00b1 1.49%. Moreover, with a comparison of single-channel classification accuracy for all channels, we successfully extracted left dorsolateral prefrontal cortex (DLPFC) and anterior prefrontal cortex (APFC) as task-related ROIs. DLPFC is activated in a number of working memory task and cognitive task, and is also known to play a key role in cognitive control and adaptation of a strategy to improve the task performance. In particular, the left DLPFC is said to be activated in verbal working memory task (Smith and Jonides, 1997).APFC is the area where highly abstract information is processed. It has also been reported that APFC and DLPFC had activated in a dual-task situation (Narender and Owe, 2004). Furthermore, activation of DLPFC and APFC is associated with the difficulties of N-back problems (Owen, 2005; Katrin et al., 2014). These observations suggest that the ROIs estimated by the proposed method are reasonable. Consequently, our proposed method has been shown to be useful for a brain function analysis of fNIRS data.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<\/p>\n<ul>\n<li>\u8cea\u7591\u5fdc\u7b54<\/li>\n<\/ul>\n<p>\u4eca\u56de\u306e\u8b1b\u6f14\u767a\u8868\u3067\u306f\uff0c\u4ee5\u4e0b\u306e\u3088\u3046\u306a\u8cea\u7591\u3092\u53d7\u3051\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>1<\/strong><br \/>\n\u8cea\u554f\u8005\u306e\u6c0f\u540d\u3092\u63a7\u3048\u640d\u306d\u3066\u3057\u307e\u3044\u307e\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306fDeep\u3000Learning\u3068\u3044\u3046\u3068\u4e2d\u8eab\u306f\u30d6\u30e9\u30c3\u30af\u30dc\u30c3\u30af\u30b9\u3068\u3055\u308c\u3066\u3044\u308b\u304c\uff0c\u3069\u306e\u3088\u3046\u306b\u3057\u3066ROI\u3092\u63a8\u5b9a\u3059\u308b\u306e\u304b\u3068\u3044\u3046\u8cea\u554f\u3067\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306b\u5bfe\u3059\u308b\u56de\u7b54\u3067\u3059\u304c\uff0cDeepLearning\u3092\u59cb\u3081\u3068\u3059\u308b\u6a5f\u68b0\u5b66\u7fd2\u30a2\u30eb\u30b4\u30ea\u30ba\u30e0\u306b\u306f\u5165\u529b\u3068\u51fa\u529b\u3092\u3064\u306a\u3050\u30d1\u30e9\u30e1\u30fc\u30bf\u304c\u5b58\u5728\u3057\uff0c\u305d\u306e\u30d1\u30e9\u30e1\u30fc\u30bf\u3092\u898b\u3066\uff0c\u5165\u529b\u307e\u3067\u305f\u3069\u308b\u3053\u3068\u3067\uff0c\u3069\u306e\u90e8\u4f4d\u304c\u8b58\u5225\u306b\u91cd\u8981\u3067\u3042\u308b\u304b\u3092\u5224\u65ad\u3067\u304d\u308b\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>2<\/strong><br \/>\n\u30c9\u30ef\u30f3\u30b4\u4eba\u5de5\u77e5\u80fd\u7814\u7a76\u6240\u6240\u9577\u306e\u5c71\u5ddd\u3055\u3093\u304b\u3089\u306e\u8cea\u554f\u3067\u3059\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306f\uff0c\u306a\u305c\u7a7a\u9593\u6027\u3068\u6642\u7cfb\u5217\u6027\u3092\u5206\u3051\u3066\u884c\u3046\u5fc5\u8981\u304c\u3042\u308b\u306e\u304b\u3068\u3044\u3046\u8cea\u554f\u3067\u3057\u305f\uff0e\u3053\u3061\u3089\u306e\u8cea\u554f\u306b\u5bfe\u3059\u308b\u56de\u7b54\u3067\u3059\u304c\uff0c\u7a7a\u9593\u6027\u3068\u6642\u7cfb\u5217\u6027\u3092\u540c\u6642\u306b\u884c\u3046\u3068\uff0c\u3069\u3053\u306b\u8b58\u5225\u306b\u5fc5\u8981\u306a\u7279\u5fb4\u91cf\u304c\u3042\u3063\u305f\u306e\u304b\u3092\u7279\u5b9a\u3059\u308b\u3053\u3068\u304c\u56f0\u96e3\u3067\u3042\u308a\uff0c\u69cb\u9020\u7684\u306b\u7279\u5b9a\u3057\u3084\u3059\u3044\u305f\u3081\u306b\uff0c\u5206\u3051\u3066\u884c\u3063\u305f\u3068\u56de\u7b54\u81f4\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ul>\n<li>\u611f\u60f3<\/li>\n<\/ul>\n<p>\u4eca\u56de\u306f\u521d\u3081\u3066\u306e\u56fd\u969b\u5b66\u4f1a\u3067\u3042\u308a\uff0c\u82f1\u8a9e\u3067\u81ea\u5206\u306e\u7814\u7a76\u5185\u5bb9\u304c\u4f1d\u308f\u308b\u306e\u304b\u3068\u3044\u3046\u4e0d\u5b89\u304c\u3042\u308a\u307e\u3057\u305f\uff0e<br \/>\n\u3057\u304b\u3057\uff0c\u65e5\u548c\u5148\u751f\u306e\u3054\u6307\u5c0e\u306e\u304a\u304b\u3052\u3067\uff0c\u30a4\u30f3\u30d1\u30af\u30c8\u306e\u3042\u308b\u30dd\u30b9\u30bf\u30fc\u3092\u4f5c\u6210\u3059\u308b\u3053\u3068\u304c\u3067\u304d\uff0c\u591a\u304f\u306e\u65b9\u306e\u76ee\u306b\u6b62\u307e\u308a\uff0c\u305d\u306e\u969b\u306b\u81ea\u5206\u306e\u7814\u7a76\u306e\u4e2d\u3067\u4e00\u756a\u4f1d\u3048\u305f\u3044\u3053\u3068\u3092\u91cd\u70b9\u306b\u8aac\u660e\u3059\u308b\u3053\u3068\u3067\u591a\u304f\u306e\u65b9\u306b\u7406\u89e3\u3057\u3066\u3082\u3089\u3046\u3053\u3068\u304c\u3067\u304d\u307e\u3057\u305f\uff0e\u305d\u3057\u3066\uff0c\u5b66\u4f1a\u53c2\u52a0\u3059\u308b\u3053\u3068\u3067\uff0c\u81ea\u5206\u306e\u767a\u8868\u306b\u5bfe\u3059\u308b\u8cb4\u91cd\u306a\u3054\u610f\u898b\u3084\u8cea\u554f\u3092\u3044\u305f\u3060\u304d\uff0c\u5927\u5909\u52c9\u5f37\u306b\u306a\u308a\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ol start=\"3\">\n<li>\u8074\u8b1b<\/li>\n<\/ol>\n<p>\u4eca\u56de\u306e\u8b1b\u6f14\u4f1a\u3067\u306f\uff0c\u4e0b\u8a18\u306e2\u4ef6\u306e\u767a\u8868\u3092\u8074\u8b1b\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">\u767a\u8868\u30bf\u30a4\u30c8\u30eb\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a\u3000Measuring complex brain networks structure<br \/>\n\u8457\u8005\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Ester Bonmati, Anton Bardera, Imma Boada<br \/>\n\u30bb\u30c3\u30b7\u30e7\u30f3\u540d\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Track E &#8211; Informatics III: Visualization<br \/>\nAbstruct\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a<br \/>\n<strong>Introduction: <\/strong>The human brain has roughly one hundred billion neurons forming a network with trillions of intra-connections. The mapping of structure and functionality of brain networks is therefore an important challenge in understanding the functioning. Connectivity matrices are used to represent brain networks, also called connectome (Hagmann, 2005; Sporns et al., 2005), as a graph (Hagmann et al., 2007, 2010; Sporns, 2013), where nodes correspond to brain regions and edges to structural or functional connections (Bullmore and Bassett, 2011; Sporns, 2011; Wu et al., 2013).<br \/>\nDifferent measures have been applied to describe topological features of brain networks (Stam and Reijneveld, 2007; Rubinov and Sporns, 2010; Kaiser, 2011). For instance, the independence of large areas, denoted as integration, has been studied by the path length measure, the characteristic path length (Watts and Strogatz, 1998), or the global efficiency (Latora and Marchiori, 2001). Independence of small subsets, defined as segregation, can be analyzed by the clustering coefficient (Watts and Strogatz, 1998), the transitivity (Newman, 2003a), or the modularity (Newman, 2003b). The importance of individual nodes can be defined with centrality measures such as the degree (Bullmore and Sporns, 2009). A good summary of the measures can be found in Rubinov and Sporns (2010).<br \/>\nIn this work, we present a global and two local measures, based on the mutual information measure, to quantify brain networks structure.<br \/>\n<strong>Materials and Methods: <\/strong><em>Materials<\/em>: Synthetic model networks were created using the Brain Connectivity Toolbox (BCT) (Rubinov and Sporns, 2010). Random, lattice, ring lattice, and small-world model networks with 128 and 256 nodes with edges ranging from 128 to 8192 with a step of 128 edges were used. Additionally, networks with nodes ranging from 32 to 512 with a step of 32 and a density of 0.4 were also created.<br \/>\nAs human structural networks, we used the normalized connection matrices created from MRI tractography described in Cammoun et al. (2012). As human functional networks, we used the HCP 500-PTN functional dataset (Van Essen et al., 2012; Glasser et al., 2013; Hodge et al., 2015).<br \/>\nAll networks were weighted and non-directed.<br \/>\n<em>Method<\/em>: In the proposed approach, brain networks are modelled as a Markov process where neuronal impulses randomly walk from one node to another node. This new interpretation provides a solid theoretical framework from which we derive a global (i.e., a single value for the whole network) and two local (i.e., a value for each node) measures based on mutual information.<br \/>\nMutual information (MI) measures the shared information between two random variables. From our Markov process-based brain model, we propose as a global connectivity measure the mutual information between two consecutive states of the process. Mutual information can also be seen as the difference between the uncertainty of the states without any knowledge and the uncertainty of the states when the past is known (or information gained when the previous node is known). The higher the MI, the less random the connections. Thus, mutual information can be used to quantify the overall brain structure.<br \/>\nThe mutual information can be decomposed in order to characterize the degree of informativeness of each state. When applied to the connectome, since each state corresponds to an anatomical or functional region, this measure can be seen as the contribution of each node to the whole graph structure. In this work, we propose two local measures. On the one hand, we use the mutual surprise (I1) (DeWeese and Meister, 1999), that expresses how \u201csurprising\u201d are the connections of a node. Nodes that are connected with more likely nodes will lead to low values of mutual surprise, while those with very specific connections or connected with few unlikely nodes will have high mutual surprise. On the other hand, we use the mutual predictability (I2) (DeWeese and Meister, 1999), that expresses the uncertainty of a node taking into account the mean connectivity of all the network. I2 measures the capacity of prediction for a given brain region.<br \/>\n<strong>Results and Discussion: <\/strong>Using model networks with different number of edges, an optimum point was found for lattice and ring lattice networks when increasing the density. This is due to the fact that for low densities, there are regions not connected, thus, the overall mutual information is low. This fact may help to find a minimum number of fibers needed to study brain networks for a given brain parcellation. Overall, higher values were obtained for lattice and ring lattice models, showing a clear evidence of more organized networks compared with random and small-world networks. When the number of edges was increased, the mutual information tended to decrease, since the higher number of connections, the lower correlation between consecutive states. Preserving the density, the mutual information was not very sensitive to random and small-world networks, since the structure is similar. Higher values were obtained for ring lattice networks when comparing with lattice networks, since in lattice networks two nodes are not connected and have a less structured network. Using anatomical and functional connectomes at different scales, a similar behavior was observed for all patients.<br \/>\nLocal measures were evaluated using the human connectomes. The mutual surprise highlighted regions connected to regions not highly connected, such as the right hemisphere transverse temporal. Low values were obtained for regions connected to highly connected regions such as the left hemisphere thalamus proper. The mutual predictability associated regions with a low number of connections and high weights with a high predictability, such us the right hemisphere temporal pole. Low values were obtained in regions with more uncertainly in predicting the next node, such as the right hemisphere putamen.<br \/>\nAll measures were consistent for structural and functional human networks.<br \/>\n<strong>Conclusion: <\/strong>In this work, new measures to quantify structure of complex brain networks are proposed. Brain connectivity graphs are interpreted as a stochastic process where neural impulses are modeled as a random walk. This interpretation provides a solid theoretical framework from which different measures based on the mutual information measure have been applied.<br \/>\nThe measures have been tested on synthetic model networks and structural and functional human networks at different scales. Results show that the mutual information is able to quantify the structure of different model networks. The mutual surprise, allows the identification of nodes whose neighbors have a high connectivity taking into account all connections. The mutual predictability shows that regions with a high clustering tend to be more predictable.<br \/>\n<strong>Acknowledgments<\/strong><br \/>\nThis work was supported by the Spanish Government (Grant No. TIN2013-47276-<br \/>\nC6-1-R) and by the Catalan Government (Grant No. 2014-SGR-1232). Data were provided, in part, by the Human Connectome Project, WU-Minn Consortium (Principal Investigators: David Van Essen and Kamil Ugurbil; 1U54MH091657) funded by the 16 NIH Institutes and Centers that support the NIH Blueprint for Neuroscience Research; and by the McDonnell Center for Systems Neuroscience at Washington University.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>\u672c\u767a\u8868\u306f\uff0c\u8133\u306e\u72b6\u614b\u306e\u9077\u79fb\u3092\u30de\u30eb\u30b3\u30d5\u904e\u7a0b\u3068\u3057\u3066\u30e2\u30c7\u30eb\u5316\u3057\uff0c\u69cb\u9020\u7684\u30b3\u30cd\u30af\u30c6\u30a3\u30d3\u30c6\u30a3\u3092\u30b0\u30e9\u30d5\u7406\u8ad6\u3092\u7528\u3044\u3066\u89e3\u6790\u3059\u308b\u3082\u306e\u3067\u3057\u305f\uff0e\u8133\u306e\u72b6\u614b\u3092\u89e3\u6790\u3059\u308b\u4e0a\u3067\u30de\u30eb\u30b3\u30d5\u9023\u9396\u3082\u691c\u8a0e\u3059\u308b\u5fc5\u8981\u304c\u3042\u308b\u3068\u611f\u3058\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">\u767a\u8868\u30bf\u30a4\u30c8\u30eb\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a\u3000Functional connectivity of resting state as a biomarker for working memory performance<br \/>\n\u8457\u8005\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Hu\u0308den Nese, Can Soylu, P\u0131nar Adanal\u0131, Metahan Irak, Ata Ak\u0131n<br \/>\n\u30bb\u30c3\u30b7\u30e7\u30f3\u540d\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Poster<br \/>\nAbstruct\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a<br \/>\nGraph theory is a powerful tool to investigate the brain as a complex system. Several studies have worked on the relation between individual difference in cognitive ability and the network organization of the brain (Li et al., 2009; van den Heuvel et al., 2009). However, this relation is still poorly understood.<br \/>\nIn this study, we investigated the relation between resting state functional connectivity and performance in a working memory task. Spontaneous EEG of 15 subjects were recorded for 2 min with closed eyes using 32-channel system. Then participants per- formed a verbal n-back task. The correlation coefficient between channel pairs during the rest period was used as a measure of functional connectivity. Connectivity matrix was thresholded according the predefined connection density. Global efficiency, local efficiency, and modularity were computed from the processed connectivity matrix, normalized, and statistically analyzed.<br \/>\nWe showed that there is a relation between functional integration and cognitive per- formance. Global efficiency is significantly correlated with performance especially in beta (r = 0.52, p = 0.045) and gamma (r = 0.58, p = 0.023) bands. Besides, there is also significant correlation between modularity and performance in beta band (r = 0.55, p = 0.33). Our results are mainly compatible with previously published studies where they reported that global efficiency and modularity are the predictors of cognitive performance regardless of the cognitive task domain (Langer et al., 2012; Stevens et al., 2012; Alavash et al., 2015). However, there are conflicting results on the local efficiency depending on the cognitive task (van den Heuvel et al., 2009; Langer et al., 2012).<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>Working Memory\u306e\u30cd\u30c3\u30c8\u30ef\u30fc\u30af\u7d50\u5408\u306b\u95a2\u3059\u308b\u767a\u8868\u3067\u3057\u305f\uff0e\u8a8d\u77e5\u8ab2\u984c\u6642\u306e\u500b\u4eba\u5dee\u306e\u95a2\u4fc2\u6027\u3092\u89e3\u6790\u306b\u3088\u308a\uff0c\u8abf\u67fb\u3059\u308b\u3068\u3044\u3046\u3082\u306e\u3067\u3057\u305f\uff0e\u4eca\u307e\u3067\uff0c\u500b\u4eba\u5dee\u306b\u3064\u3044\u3066\u306f\u691c\u8a0e\u3092\u3057\u3066\u3044\u306a\u304b\u3063\u305f\u306e\u3067\uff0c\u500b\u4eba\u3067\u8133\u6a5f\u80fd\u72b6\u614b\u304c\u3069\u306e\u3088\u3046\u306b\u5909\u5316\u3059\u308b\u306e\u304b\u4eca\u5f8c\u691c\u8a0e\u3059\u308b\u5fc5\u8981\u304c\u3042\u308b\u3068\u611f\u3058\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n\u53c2\u8003\u6587\u732e<\/p>\n<ul>\n<li>Neuroinformatics 2016,<\/li>\n<\/ul>\n<p>http:\/\/neuroinformatics2016.org\/<br \/>\n&nbsp;<br \/>\n<strong>\u5b66\u4f1a\u53c2\u52a0\u5831\u544a\u66f8<\/strong><\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"147\"><strong>\u00a0<\/strong><br \/>\n<strong>\u5831\u544a\u8005\u6c0f\u540d<\/strong><\/td>\n<td width=\"373\">&nbsp;<br \/>\n\u5409\u6b66\u3000\u6c99\u898f<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u767a\u8868\u8ad6\u6587\u30bf\u30a4\u30c8\u30eb<\/strong><\/td>\n<td width=\"373\">Adaptive HRF and BF approaches to fNIRS activation analysis<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u767a\u8868\u8ad6\u6587\u82f1\u30bf\u30a4\u30c8\u30eb<\/strong><\/td>\n<td width=\"373\">Adaptive HRF and BF approaches to fNIRS activation analysis<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u8457\u8005<\/strong><\/td>\n<td width=\"373\">\u5409\u6b66\u3000\u6c99\u898f<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u4e3b\u50ac<\/strong><\/td>\n<td width=\"373\">\u533b\u7642\u60c5\u5831\u30b7\u30b9\u30c6\u30e0\u7814\u7a76\u5ba4<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u8b1b\u6f14\u4f1a\u540d<\/strong><\/td>\n<td width=\"373\">Neuroinformatics2016<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u4f1a\u5834<\/strong><\/td>\n<td width=\"373\">University of Reading<\/td>\n<\/tr>\n<tr>\n<td width=\"147\"><strong>\u958b\u50ac\u65e5\u7a0b<\/strong><\/td>\n<td width=\"373\">2016\/09\/03-2016\/09\/04<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<br \/>\n&nbsp;<\/p>\n<ol>\n<li>\u8b1b\u6f14\u4f1a\u306e\u8a73\u7d30<\/li>\n<\/ol>\n<p>2016\/09\/03\u304b\u30892016\/09\/04\u306b\u304b\u3051\u3066\uff0cReading University\u306b\u3066\u958b\u50ac\u3055\u308c\u307e\u3057\u305fNeuroinformatics2016\u306b\u53c2\u52a0\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u4ed6\u306b\u3053\u306e\u5b66\u4f1a\u306f\uff0cincf\u306b\u3088\u3063\u3066\u4e3b\u50ac\u3055\u308c\u305f\u5b66\u4f1a\u3067\uff0c\u3053\u306e\u5b66\u4f1a\u306f\uff0c\u7d50\u679c\u306e\u5171\u6709\u3068\u89e3\u6790\u65b9\u6cd5\u306e\u63d0\u4f9b\u3092\u76ee\u7684\u3068\u3057\u3066\u958b\u50ac\u3055\u308c\u307e\u3057\u305f\uff0e\u307e\u305f\u3053\u306e\u5b66\u4f1a\u5185\u3067\u306f\uff0c\u30b3\u30f3\u30d4\u30e5\u30fc\u30bf\u30b7\u30b9\u30c6\u30e0\u3084\u753b\u50cf\u5316\uff0c\u30cd\u30c3\u30c8\u30ef\u30fc\u30af\u306e\u30e2\u30c7\u30ea\u30f3\u30b0\u304c\u30bb\u30c3\u30b7\u30e7\u30f3\u5185\u3067\u767a\u8868\u3055\u308c\u307e\u3057\u305f\uff0e<br \/>\n\u672c\u7814\u7a76\u5ba4\u304b\u3089\u4ed6\u306b\uff0c\u5ee3\u5b89\u5148\u751f\uff0c\u65e5\u548c\u5148\u751f\uff0cM1\u306e\u8429\u539f\u3055\u3093\uff0c\u7389\u57ce\u3055\u3093\u304c\u53c2\u52a0\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ol start=\"2\">\n<li>\u7814\u7a76\u767a\u8868\n<ul>\n<li>\u767a\u8868\u6982\u8981<\/li>\n<\/ul>\n<\/li>\n<\/ol>\n<p>\u79c1\u306f3\u65e5\u306e17:30\u304b\u3089\u306ePOSTER AND DEMO RECEPTION\u306b\u53c2\u52a0\u3044\u305f\u3057\u307e\u3057\u305f\uff0e\u30dd\u30b9\u30bf\u30fc\u524d\u3067\u306e\u8b70\u8ad6\u304c\u884c\u308f\u308c\u307e\u3057\u305f\uff0e<br \/>\n\u4eca\u56de\u306e\u767a\u8868\u306f\uff0cfNIRS\u306b\u3088\u308b\u8a08\u6e2c\u30c7\u30fc\u30bf\u306e\u89e3\u6790\u65b9\u6cd5\u306b\u3064\u3044\u3066\u306e\u767a\u8868\u3092\u884c\u3044\u307e\u3057\u305f\uff0e\u4ee5\u4e0b\u306b\u6284\u9332\u3092\u8a18\u8f09\u81f4\u3057\u307e\u3059\uff0e<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">Functional Near Infrared Spectroscopy is one of the measurement methods for elucidation cerebral function. Measuring cerebral bloodflow change by using fNIRS, brain activation can be judged. GLM is one of the judging methods of brain activation using cerebral bloodflow change. In GLM, brain activation is judged by regression analysis of hemodynamic model and measurement data[1][2]. This hemodynamic model is created by convolution of hemodynamic response function(HRF)[3] and rectangular function based on the experimental design. Rectangular function and HRF used in thin method is the same, regardless subjects, measurement region and experimental design. But there is a possibility HRF varies depend on brain region and tasks and within subjects[3][4]. Therefore, each HRF is not always the same as general HRF. The method using hemodynamic model made with same HRF and rectangular function can\u2019t analyze along measurement data. So, it is considered that this method is unconvincing in judging brain activation. Therefore, accurate judging method is needed. Rectangular function containing variation information of cerebral activation can be determined by optimizing the function based on measurement data. Also, measurement data can be expressed exactly by optimizing HRF containing timing information based on rectangular function and measurement data. In this way, brain activation is judged exactly. Hemodynamic model matched with fNIRS data was made by optimizing HRF after optimizing rectangular function. HRF parameters are the first peak delay, the undershoot delay and amplitude ratio between the first peak and the undershoot. In optimizing rectangular function, the size of function was determined as the amount of change after 5 seconds which is maximum arrival time. Regression analysis performs on measurement data and hemodynamic model made with rectangular function and HRF. Index of optimization is t value of regression coefficient. HRF parameters are determined when t value reaches maximum. Using 3 parameters of HRF, cerebral function of each subjects and cerebral region was examined.<br \/>\n&nbsp;<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>&nbsp;<\/p>\n<ul>\n<li>\u8cea\u7591\u5fdc\u7b54<\/li>\n<\/ul>\n<p>\u4eca\u56de\u306e\u8b1b\u6f14\u767a\u8868\u3067\u306f\uff0c\u4ee5\u4e0b\u306e\u3088\u3046\u306a\u8cea\u7591\u3092\u53d7\u3051\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>1<\/strong><br \/>\n\u4f7f\u7528\u6a5f\u5668\u3067\u3042\u308bNIRS\u306b\u3064\u3044\u3066\u306e\u8cea\u554f\u3092\u3044\u305f\u3060\u304d\u307e\u3057\u305f\uff0e\u3057\u305f\u304c\u3063\u3066NIRS\u306b\u3088\u3063\u3066\u8a08\u6e2c\u3057\u3066\u3044\u308b\u30c7\u30fc\u30bf\u304c\u5b9f\u969b\u306b\u4f55\u3092\u8a08\u6e2c\u3057\u3069\u306e\u3088\u3046\u306a\u5185\u5bb9\u3092\u8868\u3057\u3066\u3044\u308b\u306e\u304b\u3092\u8aac\u660e\u3057\u307e\u3057\u305f\uff0c\u307e\u305f\uff0c\u8a08\u6e2c\u539f\u7406\u306b\u3064\u3044\u3066\u8fd1\u8d64\u5916\u5149\u3092\u4f7f\u7528\u3057\u3066\u3044\u308b\u3053\u3068\u306a\u3069\u3092\u8aac\u660e\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>2<\/strong><br \/>\n\u30e1\u30a4\u30f3\u306e\u7d50\u679c\u304c\u4f55\u3092\u793a\u3057\u3066\u3044\u308b\u306e\u304b\u3092\u8aac\u660e\u3057\u3066\u307b\u3057\u3044\u3068\u3044\u3046\u8cea\u554f\u304c\u3042\u308a\u307e\u3057\u305f\uff0e\u3057\u305f\u304c\u3063\u3066\u79c1\u306f\uff0c\u3053\u306e\u7814\u7a76\u306e\u30b3\u30f3\u30bb\u30d7\u30c8\u304b\u3089\u8aac\u660e\u3092\u884c\u3044\u307e\u3057\u305f\uff0e\u30b3\u30f3\u30bb\u30d7\u30c8\u3068\u6bd4\u8f03\u3057\u306a\u304c\u3089\u5b9f\u969b\u306b\u51fa\u305f\u7d50\u679c\u304c\u5b9f\u884c\u8ab2\u984c\u306e\u523a\u6fc0\u306e\u5927\u304d\u3055\u3092\u793a\u3059\u3053\u3068\u304c\u3067\u304d\uff0c\u6642\u7cfb\u5217\u306e\u5909\u5316\u306b\u3088\u3063\u3066\u3069\u306e\u3088\u3046\u306b\u5909\u308f\u3063\u3066\u3044\u308b\u306e\u304b\uff0c\u307e\u305fHRF\u306e\u6700\u9069\u5316\u306b\u3088\u3063\u3066\u523a\u6fc0\u306b\u5bfe\u3059\u308b\u8840\u6d41\u53cd\u5fdc\u306e\u901f\u3055\u306e\u691c\u8a0e\u304c\u53ef\u80fd\u306b\u306a\u308b\u3053\u3068\u3092\u8aac\u660e\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>3<\/strong><br \/>\nCross-validation\u3092\u4f7f\u7528\u3057\u3066\u3044\u308b\u306e\u304b\u3092\u8cea\u554f\u3055\u308c\u307e\u3057\u305f\uff0e\u3057\u305f\u304c\u3063\u3066\u79c1\u306f\u3053\u306e\u7814\u7a76\u3067\u306f\u56de\u5e30\u5206\u6790\u3092\u4f7f\u7528\u3057\u3066\u3044\u308b\u306e\u3067\uff0c\u4f7f\u7528\u3057\u3066\u3044\u306a\u3044\u3068\u8fd4\u7b54\u3057\u307e\u3057\u305f\uff0e<br \/>\n<strong>\u00a0<\/strong><br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>4<\/strong><br \/>\n\u8ab2\u984c\u3067\u3042\u308bn-back\u30bf\u30b9\u30af\u3092\u77e5\u3089\u306a\u3044\u65b9\u304c\u591a\u304b\u3063\u305f\u306e\u3067\uff0c\u8ab2\u984c\u306e\u8aac\u660e\u3068\u96e3\u6613\u5ea6\u306b\u3088\u308a\u3069\u3046\u9055\u3046\u306e\u304b\u3092\u8aac\u660e\u3057\u307e\u3057\u305f\uff0e<br \/>\n<strong>\u30fb\u8cea\u554f\u5185\u5bb9<\/strong><strong>5<\/strong><br \/>\n\u4eca\u56de\u89e3\u6790\u3057\u3066\u3044\u308b\u30c7\u30fc\u30bf\u306fOxy-Hb\u306e\u307f\u3067\uff0cDeoxy-Hb\u306f\u4f7f\u7528\u3057\u3066\u3044\u306a\u3044\u306e\u304b\u3068\u805e\u304b\u308c\u305f\u306e\u3067<br \/>\nOxy-Hb\u306e\u307f\u4f7f\u7528\u3057\u3066\u3044\u308b\u3068\u8fd4\u7b54\u3057\u307e\u3057\u305f\uff0e\u7406\u7531\u3068\u3057\u3066Deoxy-Hb\u3067\u306eHRF\u306b\u3064\u3044\u3066\u3042\u307e\u308a\u308f\u304b\u3063\u3066\u3044\u306a\u3044\u3053\u3068\u3092\u8aac\u660e\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ul>\n<li>\u611f\u60f3<\/li>\n<\/ul>\n<p>\u767a\u8868\u524d\u306f\u81ea\u5206\u306e\u82f1\u8a9e\u304c\u3069\u3053\u307e\u3067\u901a\u3058\u308b\u306e\u304b\uff0c\u304d\u3061\u3093\u3068\u8fd4\u7b54\u3067\u304d\u308b\u306e\u304b\u3068\u4e0d\u5b89\u304c\u5927\u304d\u304b\u3063\u305f\u3067\u3059\u304c\uff0c\u5b9f\u969b\u306b\u767a\u8868\u3057\u305f\u969b\u306b\u306f\uff0c\u805e\u304d\u8fd4\u3059\u3068\u5206\u304b\u308a\u3084\u3059\u304f\u3086\u3063\u304f\u308a\u3068\u8cea\u554f\u3057\u306a\u304a\u3057\u3066\u304f\u3060\u3055\u3063\u305f\u308a\u3057\u3066\uff0c\u3000\u53d7\u3051\u7b54\u3048\u304c\u3067\u304d\u3066\u3044\u305f\u3068\u601d\u3044\u307e\u3059\uff0e\u307e\u305f\uff0c\u81ea\u5206\u304c\u60f3\u50cf\u3057\u3066\u3044\u305f\u3088\u308a\u3082NIRS\u3084HRF\u306b\u3064\u3044\u3066\u3054\u5b58\u3058\u306a\u3044\u65b9\u304c\u591a\u304b\u3063\u305f\u306e\u3067\uff0c\u8aac\u660e\u8cc7\u6599\u3092\u4f5c\u6210\u3057\u3066\u3044\u304f\u3079\u304d\u3060\u3063\u305f\u3068\u601d\u3044\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<ol start=\"3\">\n<li>\u8074\u8b1b<\/li>\n<\/ol>\n<p>\u4eca\u56de\u306e\u8b1b\u6f14\u4f1a\u3067\u306f\uff0c\u4e0b\u8a18\u306e2\u4ef6\u306e\u767a\u8868\u3092\u8074\u8b1b\u3057\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">\u767a\u8868\u30bf\u30a4\u30c8\u30eb\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a\u3000Whole brain fMRI activity at a high temporal resolution: A novel analytic framework<br \/>\n\u8457\u8005\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a \u00a0Niels Janssen<br \/>\n\u30bb\u30c3\u30b7\u30e7\u30f3\u540d\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Neuroimaging I<br \/>\nAbstruct\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a We have developed a new framework for the analysis of functional Magnetic Resonance Imaging (fMRI) data. Whereas current analytic techniques primarily yield static, time-invariant maps of fMRI activity (Smith et al., 2004), our new technique yields dynamic, time-variant videos of whole-brain fMRI activity. The new framework relies on a fundamentally different method of fMRI BOLD signal extraction. Specifically, instead of the standard volume-based signal extraction, the new method extracts the fMRI BOLD signal based on the veridical MRI slice acquisition times. This yields an fMRI signal that is more temporally accurate (Sladky et al., 2011). In addition, we improved the temporal resolution by presenting each slice to a different point in the progression of the BOLD signal [see also Price et al. (1999)]. The fMRI BOLD signal is then extracted using non-standard statistical modeling techniques. Specifically, the fMRI data are first broken up into epochs that are time-locked to the onset of a stimulus. Next, in line with techniques used in EEG (Janssen et al., 2014), statistical models are run at each time-point in the epoch. As the baseline, we used the fMRI signal intensity values available at time-point 0. For this particular choice of baseline, modeling involves extracting the fMRI BOLD signal across time points in the epoch. The number of available timepoints in the epoch (and therefore the temporal resolution) is scalable, up to a maximum that is determined by the rate at which MRI slices are acquired (typically on the order of tens of milliseconds). In order to account for the full complexity of the statistical model, we used Linear Mixed Effect modeling (Pinheiro and Bates, 2000). Our method yields an fMRI signal for every voxel in the brain that is more temporally accurate and of a much higher temporal resolution that is available in current frameworks.<br \/>\nThe data manipulation in the new framework relies on functions written as part of the neuro-imaging data analysis package FSL (Smith et al., 2004) and various Python scripts of which the NiBabel package for reading neuro-imaging data forms an indispensable part (http:\/\/nipy.org\/nibabel\/). Statistical modeling of first order individual participant data relied on the data.table and lme4 packages available in the software R (Douglas et al., 2015). Higher order modeling was performed with the randomise function of FSL (Winkler et al., 2014). A key characteristic of the current approach is that it does not rely on data averaging but uses all data points from all epochs in an experiment to model the signal. Advantages of using this pipeline are that statistical modeling of first-order fMRI data is greatly simplified and handled by R. Disadvantages are the slow speed of R, and the large file sizes due to the long data table format requirements imposed by R.<br \/>\nWe will illustrate the new technique in the context of fMRI data collected during a visual object naming experiment. We will use these data to explore the spatio-temporal dynamics of the whole-brain fMRI BOLD signal at 390\u00a0ms temporal resolution, focusing on task-based functional connectivity. Our new framework can be easily applied to data collected with other types of tasks and provides a novel opportunity to gain insight into the spatio-temporal dynamics of fMRI activity during cognitive tasks.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>\u3053\u306e\u767a\u8868\u3067\u306fMRI\u30c7\u30fc\u30bf\u306e\u89e3\u6790\u624b\u6cd5\u3092\u63d0\u6848\u3057\u3066\u3044\u307e\u3057\u305f\uff0e\u523a\u6fc0\u3092\u4e0e\u3048\u305f\u6642\u306e\u30b9\u30e9\u30a4\u30b9\u3092\u7528\u3044\u3066\u30dc\u30ea\u30e5\u30fc\u30e0\u306e\u518d\u69cb\u6210\u3092\u3057\u3066\u3044\u307e\u3057\u305f\uff0e\u3053\u306e\u65b9\u6cd5\u3092\u4f7f\u7528\u3059\u308b\u3068\u523a\u6fc0\u4ed8\u8fd1\u306e\u8133\u72b6\u614b\u3092\u89b3\u5bdf\u3059\u308b\u3053\u3068\u304c\u53ef\u80fd\u306b\u306a\u3063\u3066\u3044\u307e\u3057\u305f\uff0e\u3057\u304b\u3057\uff0c\u3053\u306e\u65b9\u6cd5\u3067\u306f\u523a\u6fc0\u306b\u3088\u308b\u8133\u6d3b\u52d5\u306e\u5909\u5316\u306e\u307f\u3092\u898b\u3089\u308c\u308b\u3068\u306f\u9650\u3089\u306a\u3044\u306e\u3067\uff0c\u691c\u8a0e\u3092\u884c\u3046\u5fc5\u8981\u304c\u3042\u308b\u3068\u611f\u3058\u307e\u3057\u305f\uff0e<\/p>\n<table>\n<tbody>\n<tr>\n<td width=\"529\">\u767a\u8868\u30bf\u30a4\u30c8\u30eb\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1aMechanisms underlying different onset patterns of focal seizures<br \/>\n\u8457\u8005\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Yujiang Wang<br \/>\n\u30bb\u30c3\u30b7\u30e7\u30f3\u540d\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Brain Disorders I<br \/>\nAbstruct\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0\u00a0 \uff1a Focal seizures typically begin with an electrographic onset pattern that is highly stereotyped in individual patients. Qualitative classifications of these onset patterns describe two frequently occurring waveforms \u2013 low amplitude fast oscillations (LAF), or high amplitude spikes (HAS). Interestingly, only the former of the patterns is associated with a good surgical outcome. Given the importance of this clinical distinction, we therefore explored whether these two patterns arise from fundamentally different\u00a0 spatio-temporal dynamics.<br \/>\nWe used a previously established computational model of neocortical tissue, and validated it as an adequate model using clinical recordings of focal seizures. Using this model we then investigated the possible mechanisms underlying the different focal seizure onset patterns.<br \/>\nWe show that the two patterns are associated with different mechanisms at the spatial scale of a single ECoG electrode. The LAF onset is initiated by independent patches of localised activity, which slowly invade the surrounding tissue and coalesce over time (see Figure 1A). In contrast, the HAS onset is a global, systemic transition to a coexisting seizure state triggered by a local event (see Figure 1B). We find that such a global transition is enabled by an increase in excitability of the surrounding tissue, essentially creating a seizure supporting surrounding. In our simulations, the difference in surrounding tissue excitability also offers a simple explanation of the clinically observed difference in surgical outcomes. Finally, we demonstrate how changes in tissue excitability could be elucidated in principle using active stimulation.<br \/>\nWe conclude that the excitability of the tissue surrounding the seizure core plays a determining role in the seizure onset pattern, as well as in the surgical outcome.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>\u3053\u306e\u767a\u8868\u3067\u306f\uff0c\u3066\u3093\u304b\u3093\u306e\u767a\u4f5c\u767a\u751f\u6642\u306e\u8133\u6d3b\u52d5\u3092EEG\u3067\u8a08\u6e2c\u3057\u7814\u7a76\u3057\u3066\u3044\u307e\u3057\u305f\uff0e\u307e\u305f\uff0c\u305d\u306e\u6642\u306e\u30cb\u30e5\u30fc\u30ed\u30f3\u5909\u5316\u3092\u898b\u3066\u3044\u307e\u3057\u305f\uff0e\u3066\u3093\u304b\u3093\u306e\u767a\u751f\u306b\u306f\u7279\u5b9a\u306e\u7d30\u80de\u304c\u8d77\u56e0\u3057\u3066\u3044\u308b\u306e\u3067\u306f\u306a\u3044\u304b\u3068\u8ff0\u3079\u3066\u3044\u307e\u3057\u305f\uff0e\u3066\u3093\u304b\u3093\u306f\u591a\u304f\u306e\u65b9\u304c\u304b\u304b\u3063\u3066\u3044\u308b\u75c5\u6c17\u3067\u3082\u3042\u308b\u306e\u3067\uff0c\u7814\u7a76\u304c\u9032\u307f\u5c11\u3057\u3067\u3082QOL\u304c\u9ad8\u304f\u306a\u308b\u3068\u3044\u3044\u3068\u601d\u3063\u3066\u3044\u308b\u306e\u3067\uff0c\u3053\u306e\u3088\u3046\u306a\u7814\u7a76\u3092\u3057\u3066\u3044\u308b\u767a\u8868\u8005\u304c\u4ed6\u306b\u3082\u3044\u3066\u8208\u5473\u3092\u6301\u3063\u3066\u805e\u304f\u3053\u3068\u304c\u3067\u304d\u307e\u3057\u305f\uff0e<br \/>\n&nbsp;<br \/>\n\u53c2\u8003\u6587\u732e<br \/>\n(1) S. Tsujimoto, T. Yamamoto, H. Kawaguchi, H. Koizumi and T. Sawaguchi, \u201cPrefrontal cortical activation associated with working memory in adults and preschool<br \/>\nchildren: an event-related optical topography study,\u201d Neuroimage, vol. 1, no. 21,<\/p>\n<ol start=\"2004\">\n<li>283\u2013290, 2004.<\/li>\n<\/ol>\n<p>&nbsp;<br \/>\n(2) M. Hofmann, M. Herrmann, I. Dan, H. Obrig, M. Conrad, L. Kuchinke, A. Jacobs<br \/>\nand A. Fallgatter, \u201cDifferential activation of frontal and parietal regions during visual<br \/>\nword recognition: an optical topography study,\u201d Neuroimage, vol. 3, no. 40, pp.<br \/>\n1340\u20131349, 2008.<br \/>\n&nbsp;<br \/>\n(3) T. Sano, D. Tsuzuki, I. Dan, H. Dan, H. Yokota, K. Oguro and E. Watanabe, \u201cAdaptive hemodynamic response function to optimize differential temporal information<br \/>\nof hemoglobin signals in functional near-infrared spectroscopy,\u201d Complex Medical<br \/>\nEngineering (CME), vol. 1, no. 1, pp. 788\u2013792, 2012.<br \/>\n&nbsp;<br \/>\n(4) I. Dan, T. Sano, H. Dan and E. Watanabe, \u201cOptimizing the general linear model for<br \/>\nfunctional near-infrared spectroscopy: an adaptive hemodynamic response function<br \/>\napproach,\u201d Neurophoton, vol. 1, no. 1, pp. 015004\u2013015004, 2014.<br \/>\n&nbsp;<\/p>\n","protected":false},"excerpt":{"rendered":"<p>\u30a4\u30ae\u30ea\u30b9\u30fb\u30ec\u30c7\u30a3\u30f3\u30b0\u3067\u958b\u50ac\u3055\u308c\u305f\u3000Neuroinformatics 2016 \u306b\u7814\u7a76\u5ba4\u304b\u3089\u4e0b\u8a18\u306e3\u540d\u304c\u767a\u8868\u3057\u307e\u3057\u305f\u3002 M1 \u8429\u539f\u3000\u91cc\u5948\u00a0Functional connectivity analysis of workin &hellip; <\/p>\n<p class=\"link-more\"><a href=\"https:\/\/is.doshisha.ac.jp\/news\/?p=3683\" class=\"more-link\"><span class=\"screen-reader-text\">&#8220;\u3010\u901f\u5831\u3011\u3000Neuroinformatics 2016&#8221; \u306e<\/span>\u7d9a\u304d\u3092\u8aad\u3080<\/a><\/p>\n","protected":false},"author":2,"featured_media":0,"comment_status":"closed","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[6],"tags":[],"class_list":["post-3683","post","type-post","status-publish","format-standard","hentry","category-6"],"_links":{"self":[{"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=\/wp\/v2\/posts\/3683","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=\/wp\/v2\/users\/2"}],"replies":[{"embeddable":true,"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=%2Fwp%2Fv2%2Fcomments&post=3683"}],"version-history":[{"count":0,"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=\/wp\/v2\/posts\/3683\/revisions"}],"wp:attachment":[{"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=%2Fwp%2Fv2%2Fmedia&parent=3683"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=%2Fwp%2Fv2%2Fcategories&post=3683"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/is.doshisha.ac.jp\/news\/index.php?rest_route=%2Fwp%2Fv2%2Ftags&post=3683"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}