Presentation is loading. Please wait.

Presentation is loading. Please wait.

Electrochemical DNA Hybridization Sensors Shenmin Pan Bioanalytical Chemistry 395 Instructor: Prof. Rusling.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Electrochemical DNA Hybridization Sensors Shenmin Pan Bioanalytical Chemistry 395 Instructor: Prof. Rusling."— Presentation transcript:

1 Electrochemical DNA Hybridization Sensors Shenmin Pan Bioanalytical Chemistry 395 Instructor: Prof. Rusling

2 Outline Biosensors Electrochemical DNA Hybridization Biosensor  Four different pathways  Three types of DNA sensors Conclusion and challeges References

3 Biosensors What is biosensors: a device for the detection of an analyte that combines a biological component with a physicochemical detector component. Components of biosensors the sensitive biological element the transducer in between (associates both components) the detector element (optical, electrochemical, thermometric, or magnetic)

4 Electrochemical DNA biosensor Fig. 1 General DNA sensor design

5 DNA Hybridization Sensor Four pathways: A / in the ox./red. i p of the label which selectively binds with ds-DNA/ss-DNA A / in the ox./red. i p of electroactive DNA bases such as guanine or adenine The S. of the substrate after hybridization The S. of the nanoparticle probe attached after hybridization with the target

6

7 Focus: three types DNA-specific redox indicator detection Nanoparticle-based DNA detection Intercalator-based DNA detection

8 DNA-specific redox indicator detection Osmetech eSensor ® Fig.3 Schematic representation of eSensor

9

10 Nanoparticle-based DNA detection Example: fm detection of DNA using metal sulfide nanoparticles 5’-thiolated capture sequence DNA c1, c2, c3 on the gold substrate CdS, ZnS, PbS nanoparticles (3nm, 5nm) Conjugated with 5’-thiolated DNA reporter sequences r1, r2, r3

11 Multi-target Detection

12 Competitive Binding

13

14 Intercalator-based DNA detection Fig. 4. Basic principles of intercalative probes

15 Fig. 5. electrochemical assay for mismatches through DNA-mediated charge transport

16 Comparison of the methods Sensor typeAd.Disad. DNA-specific redoxGood sens. Sample remain unaltered Labeling step required Nano-based amplification very good sens. Well suited for multi Preparation; reliability DNA-mediated charge transport Highly sens. Suited for mismatch det. Preparation of target sample

17 Conclusion Low cost, small size, inherent sensitivity, relatively simple in data processing Most used are metal nanoparticles, photoelectrochemical detection of DNA hybridization of these metal sulfide Carbon nanotubes

18 Challenges Desirable Electrode Surface (Polymer layer electrical conductivity, amenability to probe immobilization, prevent nonspecific binding) Fabrication into large scale and useful arrays Biological complexity of a genomic DNA sample. Real biological sample and detection ( inherent complexity: purification and isolation)

19 references 1.Drummond, T.G.; Gill, M.G. Nat. Biotechnol. 2003, 21, 1192 2.Kerman, K.; Kobayashi, M.; Tamiya, E. Meas. Sci. and Technol., 2004, 15, R1 3.http://www.osmetech.com/products/esensor/http://www.osmetech.com/products/esensor/ 4.Hansen, J. A.; Mukhopadhyay, R.; Hansen, J.; Gothelf, K.V. J. Am. Chem. Soc., 2006, 128, 3860 5.Tang, X.; Bansaruntip, S.; Nakayama, N.; Yenilmez, E.; Chang, Y.; Wang, Q. Nano Lett. 2006, 6, 1632

20 Thank you!

Download ppt "Electrochemical DNA Hybridization Sensors Shenmin Pan Bioanalytical Chemistry 395 Instructor: Prof. Rusling."

Similar presentations

A Chemocapacitive sensor array for the detection of complex odors

A Chemocapacitive sensor array for the detection of complex odors
Conclusions Future work Methods Background Introduction Lily Stanley, Juan Du, and Xuan Gao Department of Physics, Case Western Reserve University Nanowire.

Conclusions Future work Methods Background Introduction Lily Stanley, Juan Du, and Xuan Gao Department of Physics, Case Western Reserve University Nanowire.
How Do We Design and Perfect Atom- and Energy-efficient Synthesis of Revolutionary New Forms of Matter with Tailored Properties? Progress on Grand Challenge.

How Do We Design and Perfect Atom- and Energy-efficient Synthesis of Revolutionary New Forms of Matter with Tailored Properties? Progress on Grand Challenge.
Frontier NanoCarbon Research group Research Center for Applied Sciences, Academia Sinica Applications of Graphitic Carbon Materials Dr. Lain-Jong Li (Lance.

Frontier NanoCarbon Research group Research Center for Applied Sciences, Academia Sinica Applications of Graphitic Carbon Materials Dr. Lain-Jong Li (Lance.
Professor: Cheng-Hsien, Liu Student: Yi-Jou, Lin Date: 2009/11/03

Professor: Cheng-Hsien, Liu Student: Yi-Jou, Lin Date: 2009/11/03
Department of Electrical and computer Eng.

Department of Electrical and computer Eng.
Non Specific Binding (NSB) in Antigen-Antibody Assays Chem 395 Spring 2007 Instructor : Dr. James Rusling Presenter : Bhaskara V. Chikkaveeraiah.

Non Specific Binding (NSB) in Antigen-Antibody Assays Chem 395 Spring 2007 Instructor : Dr. James Rusling Presenter : Bhaskara V. Chikkaveeraiah.
Spring 2005ISAT 253 Transducers and Sensors I Friday, March 18, 2005.

Spring 2005ISAT 253 Transducers and Sensors I Friday, March 18, 2005.
CHEM 395 Bioanalytical Chemistry Instructor Prof. James F. Rusling Presenter Ashwin Bhirde CarbonNanotube BIOSENSOR.

CHEM 395 Bioanalytical Chemistry Instructor Prof. James F. Rusling Presenter Ashwin Bhirde CarbonNanotube BIOSENSOR.
LOGO The development of SPR biosensor Xixian Ye 3.1.2011.

LOGO The development of SPR biosensor Xixian Ye
Nanobiosensors Sara Huefner November 6, 2006. Outline Biosensor Background –What is a Biosensor? –Components of a Biosensor –Principles of Detection Biosensors.

Nanobiosensors Sara Huefner November 6, Outline Biosensor Background –What is a Biosensor? –Components of a Biosensor –Principles of Detection Biosensors.
Reporter: Yu Ting Huang Advising Prof: Ru Jong Jeng 1.

Reporter: Yu Ting Huang Advising Prof: Ru Jong Jeng 1.
Application of Silicon Nanowire in Biosensor Student: HongPhan ID: 9735582 Professor: Cheng-Hsien Liu.

Application of Silicon Nanowire in Biosensor Student: HongPhan ID: Professor: Cheng-Hsien Liu.
Charge-Based Biosensor Using Carbon Nanotube Transistors Array Presenter: Jui-Ping Chiang.

Charge-Based Biosensor Using Carbon Nanotube Transistors Array Presenter: Jui-Ping Chiang.
Design of Health Technologies lecture 12 John Canny 10/17/05.

Design of Health Technologies lecture 12 John Canny 10/17/05.
NSF-ITR Meeting 10-05 Miniaturized Sensors Air molecules aerosols Water molecules cells, viruses.

NSF-ITR Meeting Miniaturized Sensors Air molecules aerosols Water molecules cells, viruses.
DNA Based Biosensors Yingli Fu Biological Resources Engineering University of Maryland, College Park December 10, 2003.

DNA Based Biosensors Yingli Fu Biological Resources Engineering University of Maryland, College Park December 10, 2003.
Real-Time Detection of Biological Pathogens in Urban Environments Laura Barry Hung Phan Gloria See Introduction to Biosensors Presentation 2 - 4/5/2011.

Real-Time Detection of Biological Pathogens in Urban Environments Laura Barry Hung Phan Gloria See Introduction to Biosensors Presentation 2 - 4/5/2011.
ELECTRICAL POROUS SILICON MICROARRAY FOR DNA HYBRIDIZATION DETECTION M. Archer*, D. Persaud**, K. D Hirschman**, M. Christophersen* and P. M Fauchet* *Center.

ELECTRICAL POROUS SILICON MICROARRAY FOR DNA HYBRIDIZATION DETECTION M. Archer*, D. Persaud**, K. D Hirschman**, M. Christophersen* and P. M Fauchet* *Center.
Distributed Microsystems Laboratory Integrated Interface Circuits for Chemiresistor Arrays Carina K. Leung * and Denise Wilson, Associate Professor Department.

Distributed Microsystems Laboratory Integrated Interface Circuits for Chemiresistor Arrays Carina K. Leung * and Denise Wilson, Associate Professor Department.

Similar presentations

Ads by Google