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Journal
/
Bioengineering
/
利用自动高通量微流控系统对
铜绿假单胞
菌剪切应力的活细胞分析
JoVE Journal
Bioengineering
This content is Free Access.
JoVE Journal
Bioengineering
Live Cell Analysis of Shear Stress on
Pseudomonas aeruginosa
Using an Automated Higher-Throughput Microfluidic System
Please note that all translations are automatically generated.
Click here for the English version.
利用自动高通量微流控系统对
铜绿假单胞
菌剪切应力的活细胞分析
DOI:
10.3791/58926-v
•
09:12 min
•
January 16, 2019
•
Arin L. Sutlief*
1
,
Helena Valquier-Flynn
,
Christina Wilson
,
Marco Perez
,
Hunter Kleinschmidt
,
Brett J. Schofield
,
Elizabeth Delmain
,
Andrea E. Holmes
,
Christopher D. Wentworth*
4
1
Department of Chemistry
,
Doane University
,
2
Department of Biology
,
Doane University
,
3
Department of Pathology and Microbiology
,
University of Nebraska Medical Center
,
4
Department of Physics and Engineering
,
Doane University
Chapters
00:04
Title
00:47
Equipment Startup
01:27
Microfluidic Plate Priming and Seeding
03:39
Software and Timed Biofilm Growth Experiment Setup
07:02
Results: Representative Percent Threshold Area, Total Biofilm Accumulation, Roughness Coefficient, and Textural Entropy
08:12
Conclusion
Summary
Automatic Translation
English (Original)
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Automatic Translation
在这里, 我们描述了使用高通量微流体生物反应器结合荧光显微镜来分析剪切应力对表达绿色荧光蛋白的铜绿假单
胞
菌生物膜的剪切应力影响, 包括仪器建立了生物膜覆盖、生长速率和形态特性的测定。
Tags
Live Cell Analysis
Shear Stress
Pseudomonas Aeruginosa
Automated Higher-throughput Microfluidic System
Biofilm Development
Environmental Conditions
Biofilm Growth
Behavioral Characteristics
Multi-channeled Microfluidic Plates
Statistically Significant Results
Biofilm Structure
Antibiotic Treatments
Bioremediation
Protocol
Fluorescence Module
Imaging System Controller
CCD Camera
Imaging Station
Minimal Medium
Luria-Bertani Broth
Shear Stress
Article
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