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      KCI등재 SCOPUS SCIE

      Diffusion MRI Connections in the Octopus Brain

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      https://www.riss.kr/link?id=A108050549

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      다국어 초록 (Multilingual Abstract)

      Using high angle resolution diffusion magnetic resonance imaging (HARDI) with fiber tractography analysis we map out a meso-scale con- nectome of the Octopus bimaculoides brain. The brain of this cephalopod has a qualitatively different organization than that of vertebrates, yet it exhibits complex behavior, an elaborate sensory system and high cognitive abilities. Over the last 60 years wide ranging and detailed studies of octopus brain anatomy have been undertaken, including classical histological sectioning/staining, electron microscopy and neuronal tract tracing with injected dyes. These studies have elucidated many neuronal connections within and among anatomical structures. Diffusion MRI based trac- tography utilizes a qualitatively different method of tracing connections within the brain and offers facile three-dimensional images of anatomy and connections that can be quantitatively analyzed. Twenty-five separate lobes of the brain were segmented in the 3D MR images of each of three samples, including all five sub-structures in the vertical lobe. These parcellations were used to assay fiber tracings between lobes. The connectivity matrix constructed from diffusion MRI data was largely in agreement with that assembled from earlier studies. The one major difference was that connections between the vertical lobe and more basal supra-esophageal structures present in the literature were not found by MRI. In all, 92 con- nections between the 25 different lobes were noted by diffusion MRI: 53 between supra-esophageal lobes and 26 between the optic lobes and other structures. These represent the beginnings of a mesoscale connectome of the octopus brain.
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      Using high angle resolution diffusion magnetic resonance imaging (HARDI) with fiber tractography analysis we map out a meso-scale con- nectome of the Octopus bimaculoides brain. The brain of this cephalopod has a qualitatively different organization t...

      Using high angle resolution diffusion magnetic resonance imaging (HARDI) with fiber tractography analysis we map out a meso-scale con- nectome of the Octopus bimaculoides brain. The brain of this cephalopod has a qualitatively different organization than that of vertebrates, yet it exhibits complex behavior, an elaborate sensory system and high cognitive abilities. Over the last 60 years wide ranging and detailed studies of octopus brain anatomy have been undertaken, including classical histological sectioning/staining, electron microscopy and neuronal tract tracing with injected dyes. These studies have elucidated many neuronal connections within and among anatomical structures. Diffusion MRI based trac- tography utilizes a qualitatively different method of tracing connections within the brain and offers facile three-dimensional images of anatomy and connections that can be quantitatively analyzed. Twenty-five separate lobes of the brain were segmented in the 3D MR images of each of three samples, including all five sub-structures in the vertical lobe. These parcellations were used to assay fiber tracings between lobes. The connectivity matrix constructed from diffusion MRI data was largely in agreement with that assembled from earlier studies. The one major difference was that connections between the vertical lobe and more basal supra-esophageal structures present in the literature were not found by MRI. In all, 92 con- nections between the 25 different lobes were noted by diffusion MRI: 53 between supra-esophageal lobes and 26 between the optic lobes and other structures. These represent the beginnings of a mesoscale connectome of the octopus brain.

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      참고문헌 (Reference)

      1 Flor M, "chorddiag 0.1.3" GitHub

      2 Allan Johnson G, "Whole mouse brain connectomics" 527 : 2146-2157, 2019

      3 Forkel SJ, "White matter variability, cognition, and disorders: a systematic review" 227 : 529-544, 2022

      4 Liscovitch-Brauer N, "Trade-offbetween transcriptome plasticity and genome evolution in cephalopods" 169 : 191-202, 2017

      5 Chung WS, "Toward an MRI-based mesoscale connectome of the squid brain" 23 : 100816-, 2020

      6 Koizumi M, "Three-dimensional brain atlas of pygmy squid, Idiosepius paradoxus, revealing the largest relative vertical lobe system volume among the cephalopods" 524 : 2142-2157, 2016

      7 Shomrat T, "The vertical lobe of cephalopods : an attractive brain structure for understanding the evolution of advanced learning and memory systems" 201 : 947-956, 2015

      8 Perez PV, "The selective serotonin reuptake inhibitor fluoxetine increases spontaneous afferent firing, but not mechanonociceptive sensitization, in octopus" 17 : 10-, 2017

      9 Hochner B, "The octopus: a model for a comparative analysis of the evolution of learning and memory mechanisms" 210 : 308-317, 2006

      10 Shomrat T, "The octopus vertical lobe modulates short-term learning rate and uses LTP to acquire long-term memory" 18 : 337-342, 2008

      1 Flor M, "chorddiag 0.1.3" GitHub

      2 Allan Johnson G, "Whole mouse brain connectomics" 527 : 2146-2157, 2019

      3 Forkel SJ, "White matter variability, cognition, and disorders: a systematic review" 227 : 529-544, 2022

      4 Liscovitch-Brauer N, "Trade-offbetween transcriptome plasticity and genome evolution in cephalopods" 169 : 191-202, 2017

      5 Chung WS, "Toward an MRI-based mesoscale connectome of the squid brain" 23 : 100816-, 2020

      6 Koizumi M, "Three-dimensional brain atlas of pygmy squid, Idiosepius paradoxus, revealing the largest relative vertical lobe system volume among the cephalopods" 524 : 2142-2157, 2016

      7 Shomrat T, "The vertical lobe of cephalopods : an attractive brain structure for understanding the evolution of advanced learning and memory systems" 201 : 947-956, 2015

      8 Perez PV, "The selective serotonin reuptake inhibitor fluoxetine increases spontaneous afferent firing, but not mechanonociceptive sensitization, in octopus" 17 : 10-, 2017

      9 Hochner B, "The octopus: a model for a comparative analysis of the evolution of learning and memory mechanisms" 210 : 308-317, 2006

      10 Shomrat T, "The octopus vertical lobe modulates short-term learning rate and uses LTP to acquire long-term memory" 18 : 337-342, 2008

      11 Albertin CB, "The octopus genome and the evolution of cephalopod neural and morphological novelties" 524 : 220-224, 2015

      12 Young JZ, "The number and sizes of nerve cells in Octopus" 140 : 229-254, 1963

      13 Shigeno S, "The gyri of the octopus vertical lobe have distinct neurochemical identities" 523 : 1297-1317, 2015

      14 Young JZ, "The distributed tactile memory system of Octopus" 218 : 135-176, 1983

      15 Mather JA, "The cephalopod specialties : complex nervous system, learning, and cognition" 91 : 431-449, 2013

      16 Nixon M, "The brains and lives of cephalopods" Oxford University Press 2003

      17 Young JZ, "The anatomy of the nervous system of Octopus vulgaris" Clarendon Press 1971

      18 Rorden C, "Stereotaxic display of brain lesions" 12 : 191-200, 2000

      19 Zullo L, "Small-animal 18F-FDG PET for research on Octopus vulgaris : applications and future directions in invertebrate neuroscience and tissue regeneration" 59 : 1302-1307, 2018

      20 Scheel D, "Signal use by octopuses in agonistic interactions" 26 : 377-382, 2016

      21 Garrett S, "RNA editing underlies temperature adaptation in K+ channels from polar octopuses" 335 : 848-851, 2012

      22 Maddock L, "Quantitative differences among the brains of cephalopods" 212 : 739-767, 1987

      23 Wollesen T, "Pygmy squids and giant brains : mapping the complex cephalopod CNS by phalloidin staining of vibratome sections and whole-mount preparations" 179 : 63-67, 2009

      24 Wang ZY, "Oxford research encyclopedia of neuroscience" Oxford University Press 2019

      25 Hochner B, "Octopuses" 18 : R897-R898, 2008

      26 Jiang X, "Octopus visual system : a functional MRI model for detecting neuronal electric currents without a blood-oxygenlevel-dependent confound" 72 : 1311-1319, 2014

      27 Shigeno S, "Octopus brains : the molecular architecture of functionally identified neural systems(mollusca)" 269 : 1466-1467, 2008

      28 Zullo L, "Nonsomatotopic organization of the higher motor centers in octopus" 19 : 1632-1636, 2009

      29 Imperadore P, "Neural pathways in the pallial nerve and arm nerve cord revealed by neurobiotin backfilling in the cephalopod mollusk Octopus vulgaris" 19 : 5-, 2019

      30 Liu YC, "Neural organization of the optic lobe changes steadily from late embryonic stage to adulthood in cuttlefish Sepia pharaonis" 8 : 538-, 2017

      31 Daianu M, "Multi-shell hybrid diffusion imaging (HYDI) at 7Tesla in TgF344-AD transgenic Alzheimer rats" 10 : e0145205-, 2015

      32 Liu YC, "Morphological changes of the optic lobe from late embryonic to adult stages in oval squids Sepioteuthis lessoniana" 279 : 75-85, 2018

      33 Winters GC, "Molecular organization of octopus brains: first insights into unique memory center signaling" 56 (56): e241-, 2016

      34 Yoshida MA, "Molecular evidence for convergence and parallelism in evolution of complex brains of cephalopod molluscs : insights from visual systems" 55 : 1070-1083, 2015

      35 Pungor JR, "Molecular characterization of the octopus visual system" 53 (53): e354-, 2013

      36 Kerbl A, "Micro-CT in cephalopod research : investigating the internal anatomy of a sepiolid squid using a nondestructive technique with special focus on the ganglionic system" 447 : 140-148, 2013

      37 Wang ZY, "Maternal behavior and death in the octopus" 57 (57): e440-, 2017

      38 Yeh CH, "Mapping structural connectivity using diffusion MRI : challenges and opportunities" 53 : 1666-1682, 2021

      39 Yeh FC, "Mapping immune cell infiltration using restricted diffusion MRI" 77 : 603-612, 2017

      40 Quast MJ, "MR microscopy of cobalt-labeled nerve cells and pathways in an invertebrate brain(Sepia officinalis, Cephalopoda)" 45 : 575-579, 2001

      41 Zarrella I, "Learning and memory in Octopus vulgaris : a case of biological plasticity" 35 : 74-79, 2015

      42 Joachimiak MP, "JColorGrid : software for the visualization of biological measurements" 7 : 225-, 2006

      43 Mori S, "Introduction to diffusion tensor imaging" Academic Press 65-78, 2014

      44 Mori S, "Introduction to diffusion tensor imaging" Academic Press 79-96, 2014

      45 Butler-Struben HM, "In vivo recording of neural and behavioral correlates of anesthesia induction, reversal, and euthanasia in cephalopod molluscs" 9 : 109-, 2018

      46 Blackband SJ, "In vivo nuclear magnetic resonance imaging and spectroscopy of aquatic organisms" 8 : 191-198, 1990

      47 Ziegler A, "Holistic description of new deep sea megafauna(Cephalopoda : Cirrata)using a minimally invasive approach" 19 : 81-, 2021

      48 Hochner B, "Handbook of behavioral neuroscience" Elsevier 303-317, 2013

      49 Yeh FC, "Generalized q-sampling imaging" 29 : 1626-1635, 2010

      50 Fornito A, "Fundamentals of brain network analysis" Academic Press 89-113, 2016

      51 Hochner B, "Functional and comparative assessments of the octopus learning and memory system" 2 : 764-771, 2010

      52 Schindelin J, "Fiji : an open-source platform for biological-image analysis" 9 : 676-682, 2012

      53 Levy G, "Embodied organization of Octopus vulgaris morphology, vision, and locomotion" 8 : 164-, 2017

      54 Gray EG, "Electron microscopy of the gliovascular organization of the brain of Octopus" 255 : 13-32, 1969

      55 Pugliese C, "Effect of different formulations of magnesium chloride used as anesthetic agents on the performance of the isolated heart of Octopus vulgaris" 7 : 610-, 2016

      56 Strugnell J, "Divergence time estimates for major cephalopod groups: evidence from multiple genes" 22 : 89-96, 2006

      57 Ziegler A, "Digital three-dimensional imaging techniques provide new analytical pathways for malacological research" 36 : 248-273, 2018

      58 Jeurissen B, "Diffusion MRI fiber tractography of the brain" 32 : e3785-, 2019

      59 Sakurai Y, "Development of a contrastenhanced micro computed tomography protocol for the oval squid (Sepioteuthis lessoniana ) brain" 82 : 1941-1952, 2019

      60 Yeh FC, "Deterministic diffusion fiber tracking improved by quantitative anisotropy" 8 : e80713-, 2013

      61 Caruyer E, "Design of multishell sampling schemes with uniform coverage in diffusion MRI" 69 : 1534-1540, 2013

      62 Minnocci A, "Cryo-scanning electron microscopy investigation of the Octopus vulgaris arm structures for the design of an octopus-like arm artefact" 78 : 1133-1145, 2015

      63 Melzner F, "Coordination between ventilatory pressure oscillations and venous return in the cephalopod Sepia officinalis under control conditions, spontaneous exercise and recovery" 177 : 1-17, 2007

      64 De Lisa E, "Conservative nature of oestradiol signalling pathways in the brain lobes of Octopus vulgaris involved in reproduction, learning and motor coordination" 24 : 275-284, 2012

      65 Saidel WM, "Connections of the octopus optic lobe : an HRP study" 206 : 346-358, 1982

      66 Chung WS, "Complex visual adaptations in squid for specific tasks in different environments" 8 : 105-, 2017

      67 Young JZ, "Comparative neuroscience and neurobiology" Birkhäuser 97-99, 1988

      68 Chung WS, "Comparative brain structure and visual processing in octopus from different habitats" 32 : 97-110, 2022

      69 Wild E, "Comparative 3D microanatomy and histology of the eyes and central nervous systems in coleoid cephalopod hatchlings" 15 : 37-64, 2015

      70 Kröger B, "Cephalopod origin and evolution: a congruent picture emerging from fossils, development and molecules: extant cephalopods are younger than previously realised and were under major selection to become agile, shell-less predators" 33 : 602-613, 2011

      71 Young JZ, "Cephalopod neurobiology: neuroscience studies in squid, octopus and cuttlefish" Oxford University Press 431-443, 1995

      72 Williamson R, "Cephalopod neural networks" 13 : 87-98, 2004

      73 Darmaillacq AS, "Cephalopod cognition" Cambridge University Press 2014

      74 Shigeno S, "Cephalopod brains : an overview of current knowledge to facilitate comparison with vertebrates" 9 : 952-, 2018

      75 Hanlon RT, "Cephalopod behaviour" Cambridge University Press 2018

      76 Budelmann BU, "Central pathways of the nerves of the arms and mantle of Octopus" 310 : 109-122, 1985

      77 Robertson JD, "Carbocyanine dye labeling reveals a new motor nucleus in octopus brain" 328 : 485-500, 1993

      78 Sotiropoulos SN, "Building connectomes using diffusion MRI: why, how and but" 32 : e3752-, 2019

      79 Jaaro H, "Building complex brains--missing pieces in an evolutionary puzzle" 68 : 191-195, 2006

      80 Wirz K, "Biometric study of the nervous system of cephalopods" 93 : 78-117, 1959

      81 Caldwell RL, "Behavior and body patterns of the Larger Pacific Striped Octopus" 10 : e0134152-, 2015

      82 Gutnick T, "Animal behavior: socializing octopus" 28 : R1147-R1149, 2018

      83 Scheel D, "A second site occupied by Octopus tetricus at high densities, with notes on their ecology and behavior" 50 : 285-291, 2017

      84 Oh SW, "A mesoscale connectome of the mouse brain" 508 : 207-214, 2014

      85 Edsinger E, "A conserved role for serotonergic neurotransmission in mediating social behavior in octopus" 28 : 3136-3142, 2018

      86 Merlet S, "A computational diffusion MRI and parametric dictionary learning framework for modeling the diffusion signal and its features" 17 : 830-843, 2013

      87 Seung-Hyun Jung ; Ha Yeun Song ; Young Se Hyun ; Yu-Cheol Kim ; 황일선 ; 최태영 ; 조선미, "A Brain Atlas of the Long Arm Octopus,Octopus minor" 한국뇌신경과학회 27 (27): 257-266, 2018

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