BACKGROUND: Modern molecular tools make it possible to manipulate neural activity in a reversible and cell-type specific manner. For rhesus monkey research, molecular tools are generally introduced via viral vectors. New instruments designed specifically for use in monkey research are needed to enhance the efficiency and reliability of vector delivery. NEW METHOD: A suite of multi-channel injection devices was developed to permit efficient and uniform vector delivery to cortical regions of the monkey brain. Manganese was co-infused with virus to allow rapid post-surgical confirmation of targeting accuracy using MRI. A needle guide was designed to increase the accuracy of sub-cortical targeting using stereotaxic co-ordinates. RESULTS: The multi-channel injection devices produced dense, uniform coverage of dorsal surface cortex, ventral surface cortex, and intra-sulcal cortex, respectively. Co-infusion of manganese with the viral vector allowed for immediate verification of injection accuracy. The needle guide improved accuracy of targeting sub-cortical structures by preventing needle deflection. COMPARISON WITH EXISTING METHOD(S): The current methods, hand-held injections or single slow mechanical injection, for surface cortex transduction do not, in our hands, produce the density and uniformity of coverage provided by the injector arrays and associated infusion protocol. CONCLUSIONS: The efficiency and reliability of vector delivery has been considerably improved by the development of new methods and instruments. This development should facilitate the translation of chemo- and optogenetic studies performed in smaller animals to larger animals such as rhesus monkeys. Published by Elsevier B.V.
BACKGROUND: Modern molecular tools make it possible to manipulate neural activity in a reversible and cell-type specific manner. For rhesus monkey research, molecular tools are generally introduced via viral vectors. New instruments designed specifically for use in monkey research are needed to enhance the efficiency and reliability of vector delivery. NEW METHOD: A suite of multi-channel injection devices was developed to permit efficient and uniform vector delivery to cortical regions of the monkey brain. Manganese was co-infused with virus to allow rapid post-surgical confirmation of targeting accuracy using MRI. A needle guide was designed to increase the accuracy of sub-cortical targeting using stereotaxic co-ordinates. RESULTS: The multi-channel injection devices produced dense, uniform coverage of dorsal surface cortex, ventral surface cortex, and intra-sulcal cortex, respectively. Co-infusion of manganese with the viral vector allowed for immediate verification of injection accuracy. The needle guide improved accuracy of targeting sub-cortical structures by preventing needle deflection. COMPARISON WITH EXISTING METHOD(S): The current methods, hand-held injections or single slow mechanical injection, for surface cortex transduction do not, in our hands, produce the density and uniformity of coverage provided by the injector arrays and associated infusion protocol. CONCLUSIONS: The efficiency and reliability of vector delivery has been considerably improved by the development of new methods and instruments. This development should facilitate the translation of chemo- and optogenetic studies performed in smaller animals to larger animals such as rhesus monkeys. Published by Elsevier B.V.
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Authors: Nicholas J Szerlip; Stuart Walbridge; Linda Yang; Paul F Morrison; Jeffrey W Degen; S Taylor Jarrell; Joshua Kouri; P Benjamin Kerr; Robert Kotin; Edward H Oldfield; Russell R Lonser Journal: J Neurosurg Date: 2007-09 Impact factor: 5.115
Authors: Mark A G Eldridge; Walter Lerchner; Richard C Saunders; Hiroyuki Kaneko; Kristopher W Krausz; Frank J Gonzalez; Bin Ji; Makoto Higuchi; Takafumi Minamimoto; Barry J Richmond Journal: Nat Neurosci Date: 2015-12-14 Impact factor: 24.884
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Authors: Sébastien Tremblay; Leah Acker; Arash Afraz; Daniel L Albaugh; Hidetoshi Amita; Ariana R Andrei; Alessandra Angelucci; Amir Aschner; Puiu F Balan; Michele A Basso; Giacomo Benvenuti; Martin O Bohlen; Michael J Caiola; Roberto Calcedo; James Cavanaugh; Yuzhi Chen; Spencer Chen; Mykyta M Chernov; Andrew M Clark; Ji Dai; Samantha R Debes; Karl Deisseroth; Robert Desimone; Valentin Dragoi; Seth W Egger; Mark A G Eldridge; Hala G El-Nahal; Francesco Fabbrini; Frederick Federer; Christopher R Fetsch; Michal G Fortuna; Robert M Friedman; Naotaka Fujii; Alexander Gail; Adriana Galvan; Supriya Ghosh; Marc Alwin Gieselmann; Roberto A Gulli; Okihide Hikosaka; Eghbal A Hosseini; Xing Hu; Janina Hüer; Ken-Ichi Inoue; Roger Janz; Mehrdad Jazayeri; Rundong Jiang; Niansheng Ju; Kohitij Kar; Carsten Klein; Adam Kohn; Misako Komatsu; Kazutaka Maeda; Julio C Martinez-Trujillo; Masayuki Matsumoto; John H R Maunsell; Diego Mendoza-Halliday; Ilya E Monosov; Ross S Muers; Lauri Nurminen; Michael Ortiz-Rios; Daniel J O'Shea; Stéphane Palfi; Christopher I Petkov; Sorin Pojoga; Rishi Rajalingham; Charu Ramakrishnan; Evan D Remington; Cambria Revsine; Anna W Roe; Philip N Sabes; Richard C Saunders; Hansjörg Scherberger; Michael C Schmid; Wolfram Schultz; Eyal Seidemann; Yann-Suhan Senova; Michael N Shadlen; David L Sheinberg; Caitlin Siu; Yoland Smith; Selina S Solomon; Marc A Sommer; John L Spudich; William R Stauffer; Masahiko Takada; Shiming Tang; Alexander Thiele; Stefan Treue; Wim Vanduffel; Rufin Vogels; Matthew P Whitmire; Thomas Wichmann; Robert H Wurtz; Haoran Xu; Azadeh Yazdan-Shahmorad; Krishna V Shenoy; James J DiCarlo; Michael L Platt Journal: Neuron Date: 2020-10-19 Impact factor: 18.688