Bacterial Cell Printing
作者: Bradley R. Ringeisen , Lisa A. Fitzgerald , Stephen E. Lizewski , Justin C. Biffinger , Peter K. Wu
DOI: 10.1007/978-90-481-9145-1_14
关键词: Engineering 、 Nanotechnology 、 Bacterial cell structure 、 Microbial fuel cell 、 Genetically engineered 、 High resolution
摘要: The evolution of cell printing has made the prospect tissues and organs a feasible technological goal. With much attention given to potential impacts in medical community, less interest been directed towards ability these same technologies print living bacteria. applications ranging from isolation bacteria human infections or environmental samples purification carbon nanotubes containing thin films, prospects utilizing deposit high resolution patterns should be considered. This chapter will first give experimental details three types printers with demonstrated capabilities bacteria: ink jet, electrohydrodynamic jetting modified laser induced forward transfer (LIFT). We then summarize some recent results including deposition genetically engineered samples. also show that single cells can printed using techniques, potentially allowing bacterium isolated highly complex, multi-strain cultures end by discussing different discuss applications.
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sci-hub.st 参考文章(39)
Jong-Kyung Lee, Da-Wa Jung, Kisun Yoon, No-Seong Kwak, Sun-Kyung Yoon, Effect of Diluent Salt Concentration and pH on the Enumeration of Vibrio parahaemolyticus by Direct Plating on Selective Agar Food Science and Biotechnology. ,vol. 15, pp. 42- 46 ,(2006)
K.J. NYE, T. TURNER, D.J. COLEMAN, D. FALLON, B. GEE, S. MESSER, R.E. WARREN, N. ANDREWS, A comparison of the isolation rates of Salmonella and thermophilic Campylobacter species after direct inoculation of media with a dilute faecal suspension and undiluted faecal material. Journal of Medical Microbiology. ,vol. 50, pp. 659- 662 ,(2001) , 10.1099/0022-1317-50-8-659
J. A. Barron, H. D. Young, D. D. Dlott, M. M. Darfler, D. B. Krizman, B. R. Ringeisen, Printing of protein microarrays via a capillary-free fluid jetting mechanism. Proteomics. ,vol. 5, pp. 4138- 4144 ,(2005) , 10.1002/PMIC.200401294
Napachanok Mongkoldhumrongkul, Steve Best, Emma Aarons, Suwan N. Jayasinghe, Bio-electrospraying whole human blood: analysing cellular viability at a molecular level. Journal of Tissue Engineering and Regenerative Medicine. ,vol. 3, pp. 562- 566 ,(2009) , 10.1002/TERM.185
Vladimir Mironov, Thomas Boland, Thomas Trusk, Gabor Forgacs, Roger R. Markwald, Organ printing: computer-aided jet-based 3D tissue engineering Trends in Biotechnology. ,vol. 21, pp. 157- 161 ,(2003) , 10.1016/S0167-7799(03)00033-7
Jason A. Barron, David B. Krizman, Bradley R. Ringeisen, Laser printing of single cells: statistical analysis, cell viability, and stress. Annals of Biomedical Engineering. ,vol. 33, pp. 121- 130 ,(2005) , 10.1007/S10439-005-8971-X
Jack Merrin, Stanislas Leibler, John S. Chuang, Printing Multistrain Bacterial Patterns with a Piezoelectric Inkjet Printer PLoS ONE. ,vol. 2, pp. e663- ,(2007) , 10.1371/JOURNAL.PONE.0000663
Bradley R. Ringeisen, Christina M. Othon, Jason A. Barron, Daniel Young, Barry J. Spargo, Jet-based methods to print living cells. Biotechnology Journal. ,vol. 1, pp. 930- 948 ,(2006) , 10.1002/BIOT.200600058
Jonathan D W Clarke, Suwan N Jayasinghe, Bio-electrosprayed multicellular zebrafish embryos are viable and develop normally. Biomedical Materials. ,vol. 3, pp. 011001- 011001 ,(2008) , 10.1088/1748-6041/3/1/011001
Xiaohong Wang, Yongnian Yan, Yuqiong Pan, Zhuo Xiong, Haixia Liu, Jie Cheng, Feng Liu, Feng Lin, Rendong Wu, Renji Zhang, Qingping Lu, Generation of three-dimensional hepatocyte/gelatin structures with rapid prototyping system. Tissue Engineering. ,vol. 12, pp. 83- 90 ,(2006) , 10.1089/TEN.2006.12.83