87,860 research outputs found

    g1-choi/extractFSCVspikes: extractFSCVspikes

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    <p>extractSpikesFSCV(subject,sessnum,varargin) is the main function subject = 'patra' for our example data sessnum = session number (integer)</p> <p>%%Example Calls to extractSpikesFSCV</p> <p>extractSpikesFSCV('patra',127,'sites',{'p1','p3','pl3','cl1','cl3'},'nlx') extractSpikesFSCV('patra',83,'sites',{'p1','p5','pl1','cl3','cl6'},'nlx')</p&gt

    g1-choi/fscvartifactcreation: fscvartifactcreation

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    <p>All files used to create the artifacts are in artifact_creation. The files are labeled by their respective artifact type: createfscvartifactrctype_railtype creates a rail type artifact and saves as a CSC file for processing in plexon, for a clean input CSC file. createfscvartifactrctype_RCtype creates an RC type artifact and saves as a CSC file for processing in plexon, for a clean input CSC file. createfscvartifactrctype_rtype creates an r type artifact and saves as a CSC file for processing in plexon, for a clean input CSC file.</p> <p>These files work on a per channel basis after running the script example_getephysdata to load the csc files. An example of the loop I use for one session can be seen below: session='98b'; % string that has all the channels=[4 5 8 9 12]; % all the csc channel numbers that you want to add and remove artifact from % from the spreadsheet for corresponding CSC. a cell or strings. commasep for u=1:length(channels) selectcsc=channels(u); %CSC channel number change here pathnlx=['Z:\data_MIT\patra_fscv\patra_chronic98b_07022018\spikes']; % where you have the original CSC example_getephysdata createfscvartifactrctype_RCtype end</p> <p>Additional code needed for these to run are in Nlx_411 and dg_lib</p> <p>All the data used for the analysis is in the data files folder uploaded on Zenodo. In the data files folder the data is organized by session. In each session folder is the .mat files used for percent recovery calculations. The R, RC, and Rail folders contain the channels with the simulated artifacts saved as plexon files. The interpolated versions of these files are under the interp folder, separated into folders by artifact type. All the data used for the PC plots in the paper are under session 65 in the PC_plots folder</p&gt

    Franny Choi, 41st Annual ODU Literary Festival

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    Franny Choi is a queer, Korean-American poet, playwright, teacher, organizer, pottymouth, GryffinClaw, and general overachiever. She is the author of Floating, Brilliant, Gone (2014), and a chapbook, Death by Sex Machine (2017). She has received awards from the Poetry Foundation and the Helen Zell Writers Program, as well as fellowships from the Vermont Studio Center and the Rhode Island State Council on the Arts. Her poems have appeared in journals including Poetry magazine, American Poetry Review, New England Review, and her work has been featured by the Huffington Post, PBS NewsHour, and Angry Asian Man

    joungmin-choi/moSCminer: moSCminer v1.0.0

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    <p>Published version from the PeerJ paper</p&gt

    Biodistribution of <sup>177</sup>Lu-CHOI-3.1 in mice bearing OHS xenografts.

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    Biodistribution of 177Lu-labeled chimeric OI-3 IgG1 isotype antibody (CHOI-3.1) in tissues of interest in OHS xenograft-carrying nude mice. At each time point from three to six animals were used, with number of tumors ranging from five to twelve per group. Straight lines have been drawn to connect the data points. The error bars correspond to the standard error of the mean.</p

    MG-Choi/indoorCont: Indoor pedestrian movement simulation

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    &lt;p&gt;This model is to simulate the amount of contact that occurs between people throughout indoor social activity&lt;/p&gt

    MG-Choi/sequentPSS: Sequential Parameter Space Searching Calibration method

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    &lt;p&gt;This repository includes code and data to run SPS (Sequential Parameter Space search method).&lt;/p&gt

    ji woo choi

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    학위논문(석사)--아주대학교 일반대학원 :의학과,2015. 2ACKNOWLEDGEMENT ⅰ ABSTRACT ⅱ TABLE OF CONTENTS ⅲ LIST OF FIGURES ⅳ LIST OF TABLES ⅴ ABBEREVIATION Ⅰ. INTRODUCTION 1 Ⅱ. MATERIALS AND METHODS 2 Ⅲ. RESULTS 4 Ⅳ. DISCUSSION 11 REFERENCES 13MasterBackground. The aim of this study is to investigate the clinical factors affecting on the complete rate from the clinical pathway in minimally invasive and open surgery for gastric cancer, and to establish a subgroup of patients who can be applied by the early recovery after surgery program through this retrospective analysis. Methods. In this retrospective study, we analyzed 425 patients who underwent gastric cancer surgery from January 2011 to December 2011 and were managed with conventional clinical pathway. This clinical pathway was made as the patients in minimally invasive surgery group start the diet and discharge from hospital one day faster than them in open surgery group. Results. The completion rate of the clinical pathway was 62.4%. Despite the different applications of clinical pathway, completion rate in minimally invasive surgery group was significantly higher than it in open group (P< .001).In multivariate analysis, the surgical procedure of minimally invasive surgery (Odd ratio = 4.281) was most predictable factor to complete clinical pathway. Additionally, younger patients (Odd ratio = 1.933) who underwent distal gastrectomy (Odd ratio = 1.999) without combined resection (Odd ratio = 3.069) were predicted to accomplish the clinical pathway without modifications. Conclusion. We concluded that high efficacy of the clinical pathway for gastric cancer surgery was expected to selected patients through retrospective analysis (Expected complete rate = 85.4%). In addition, these patients would become enrolled criteria for early recovery program in gastric cancer surgery

    The Effects of Biochar and Raising Mycorrhiza Usage on Several Mineral Ingredient of Pak Choi

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    This study aims to determine the effect of biochar and increasing mycorrhiza applications on some mineral material content of pak choi plant. In the beginning of the experiment, 300 g/m(2) parcel biochar was used for each parcel one month before seedling planting. Then, increasing mycorrhiza doses per plant (0, 15, 20, 30 and 40 mL) were used to the parcels undergoing biochar application and the harvest occurred 54 days after seed sowing. The findings revealed important increases in some macro and micro nutrient element contents of Pak Choi plant with biochar and increasing mycorrhiza applications. The contents were found as P (0.41 %, 0.46 %, 0.47 %, 0.49 % and 0.56 %), K (4.33 %, 4.19 %, 4.06 %, 4.17 % and 4.59 %), Ca (2.03 %, 2.24 %, 2.17 %, 2.25 % and 2.47 %), Mg (0.15 %, 0.16 %, 0.17 %, 0.17 % and 0.20 %), Fe (569 mg/kg, 973 mg/kg, 1016 mg/kg, 1016 mg/kg and 1094 mg/kg), Cu (5.02 mg/kg, 6.26 mg/kg, 6.58 mg/kg, 7.04 mg/kg and 13.16 mg/kg), Mn (62.73 mg/kg, 74.03 mg/kg, 78.00 mg/kg, 85.96 mg/kg and 114.10 mg/kg) and Zn (37.23 mg/kg, 41.36 mg/kg, 42.03 mg/kg, 43.53 mg/kg and 52.83 mg/kg), respectively. Some macro (P, K, Ca and Mg) and micro (Fe, Cu, Zn and Mn) element contents were determined statistically significant at the level of 5 %. The best nutrient element contents of pak choi plant were obtained at V. dose: 40 mL /plant mycorrhiza applications

    Global supply chain transformation: achieving 3Rs with the GREAT strategy

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    Pandemics, hurricanes, earthquakes, fires, and other unexpected disruptions cause crises which can damage global supply chain operations. Xiaoyan Xu, Suresh P. Sethi, Sai-Ho Chung, and Tsan-Ming Choi propose the GREAT strategy to help leaders weather these crises by transforming the global supply chain to achieve the 3Rs: responsiveness, resilience, and restoration
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