Biology Reference
In-Depth Information
91. Liu F, Zhang J, Deng Y, Wang D, Lu Y, Yu X . Detection of EGFR on living human
gastric cancer BGC823 cells using surface plasmon resonance phase sensing. Sensors and
Actuators B: Chemical 2011; 153 :398-403 .
92. Cohen-Karni T, Qing Q, Li Q, Fang Y, Lieber CM. Graphene and nanowire transistors
for cellular interfaces and electrical recording. Nano Letter 2010; 10 :1098-102 .
93. Mohanty N, Berry V. Graphene-based single-bacterium resolution biodevice and
DNA transistor: interfacing graphene derivatives with nanoscale and microscale bio-
components. Nano Letters 2008; 8 :4469-76 .
94. Feng L, Chen Y, Ren J, Qu X. A graphene functionalized electrochemical aptasensor
for selective label-free detection of cancer cells. Biomaterials 2011; 32 :2930-7 .
95. Guo CX, Zheng XT, Lu ZS, Lou XW, Li CM. Biointerface by cell growth on layered
graphene-artificial peroxidase-protein nanostructure for in situ quantitative molecular
detection. Advanced Materials 2010; 22 :5164-7 .
96. He Q, Sudibya HG, Yin Z, Wu S , Li H, Boey F, et al. Centimeter-long and large-scale
micropatterns of reduced graphene oxide films: fabrication and sensing applications.
ACS Nano 2010; 4 :3201-8 .
97. Mannoor MS, Tao H, Clayton JD, Sengupta A, Kaplan DL, Naik RR, et al.
Graphene-based wireless bacteria detection on tooth enamel. Nature Communications
2012; 3 :763 .
98. Kempaiah R, Chung A, Maheshwari V. Graphene as cellular interface: electrome-
chanical coupling with cells. ACS Nano 2011; 5 :6025-31 .
99. Webster TA, Goluch ED. Electrochemical detection of pyocyanin in nanochan-
nels with integrated palladium hydride reference electrodes. Lab on Chip 2012; 12 :
5195-201 .
100. Tolosa VM, Wassum KM, Maidment NT, Monbouquette HG. Electrochemically
deposited iridium oxide reference electrode integrated with an electroenzymatic
glutamate sensor on a multi-electrode array microprobe. Biosensors and Bioelectronics
2013; 42 :256-60 .
101. Shen Q, You S-K, Park S-G, Jiang H, Guo D, Chen B, et al. Electrochemical biosens-
ing for cancer cells based on TiO 2 /CNT nanocomposites modified electrodes. Electro-
analysis 2008; 20 :2526-30 .
102. Xiao F, Song J, Gao H, Zan X, Xu R, Duan H. Coating graphene paper with
2D-assembly of electrocatalytic nanoparticles: a modular approach toward high-
performance flexible electrodes. ACS Nano 2011; 6 :100-10 .
103. Wan J, Yan X, Ding J, Ren R. A simple method for preparing biocompatible composite
of cellulose and carbon nanotubes for the cell sensor. Sensors and Actuators B: Chemical
2010; 146 :221-5 .
104. Mukhopadhyay R. When PDMS isn't the best. Analytical Chemistry 2007; 79 :3248-53 .
105. Kurian A, Prasad S, Dhinojwala A. Unusual surface aging of poly(dimethylsiloxane)
elastomers. Macromolecules 2010; 43 :2438-43 .
106. Cheung K. Implantable microscale neural interface. Biomedical Microdevices 2007;
9 :923-38 .
107. Myllymaa S, Myllymaa K, Korhonen H, Töyräs J, Jääskeläinen JE, Djupsund K, et al.
Fabrication and testing of polyimide-based microelectrode arrays for cortical mapping
of evoked potentials. Biosensors and Bioelectronics 2009; 24 :3067-72 .
108. González C, Rodríguez M. A flexible perforated microelectrode array probe for
action potential recording in nerve and muscle tissues. Journal of Neuroscience Methods
1997; 72 :189-95 .
109. Giovangrandi L, Gilchrist KH, Whittington RH, Kovacs GTA. Low-cost microelec-
trode array with integrated heater for extracellular recording of cardiomyocyte cultures
using commercial flexible printed circuit technology. Sensors and Actuators B: Chemical
2006; 113 :545-54 .
Search WWH ::




Custom Search