Chip-based Sensors for Disease Diagnosis

Nucleic acid analysis is one of the most important disease diagnostic approaches in medical practice, and has been commonly used in cancer biomarker detection, bacterial speciation and many other fields in laboratory. Currently, the application of powerful research methods for genetic analysis, incl...

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Main Author: Fang, Zhichao
Other Authors: Kelley, Shana O.
Language:en_ca
Published: 2010
Subjects:
Online Access:http://hdl.handle.net/1807/32039
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-OTU.1807-320392013-11-02T03:42:46ZChip-based Sensors for Disease DiagnosisFang, ZhichaoSensorsDiagnosisEletrochemistryNanotechnology04910572Nucleic acid analysis is one of the most important disease diagnostic approaches in medical practice, and has been commonly used in cancer biomarker detection, bacterial speciation and many other fields in laboratory. Currently, the application of powerful research methods for genetic analysis, including the polymerase chain reaction (PCR), DNA sequencing, and gene expression profiling using fluorescence microarrays, are not widely used in hospitals and extended-care units due to high-cost, long detection times, and extensive sample preparation. Bioassays, especially chip-based electrochemical sensors, may be suitable for the next generation of rapid, sensitive, and multiplexed detection tools. Herein, we report three different microelectrode platforms with capabilities enabled by nano- and microtechnology: nanoelectrode ensembles (NEEs), nanostructured microelectrodes (NMEs), and hierarchical nanostructured microelectrodes (HNMEs), all of which are able to directly detect unpurified RNA in clinical samples without enzymatic amplification. Biomarkers that are cancer and infectious disease relevant to clinical medicine were chosen to be the targets. Markers were successfully detected with clinically-relevant sensitivity. Using peptide nucleic acids (PNAs) as probes and an electrocatalytic reporter system, NEEs were able to detect prostate cancer-related gene fusions in tumor tissue samples with 100 ng of RNA. The development of NMEs improved the sensitivity of the assay further to 10 aM of DNA target, and multiplexed detection of RNA sequences of different prostate cancer-related gene fusion types was achieved on the chip-based NMEs platform. An HNMEs chip integrated with a bacterial lysis device was able to detect as few as 25 cfu bacteria in 30 minutes and monitor the detection in real time. Bacterial detection could also be performed in neat urine samples. The development of these versatile clinical diagnostic tools could be extended to the detection of various cancers, genetic, and infectious diseases.Kelley, Shana O.2010-112012-01-18T16:10:27ZWITHHELD_ONE_YEAR2012-01-18T16:10:27Z2012-01-18Thesishttp://hdl.handle.net/1807/32039en_ca
collection NDLTD
language en_ca
sources NDLTD
topic Sensors
Diagnosis
Eletrochemistry
Nanotechnology
0491
0572
spellingShingle Sensors
Diagnosis
Eletrochemistry
Nanotechnology
0491
0572
Fang, Zhichao
Chip-based Sensors for Disease Diagnosis
description Nucleic acid analysis is one of the most important disease diagnostic approaches in medical practice, and has been commonly used in cancer biomarker detection, bacterial speciation and many other fields in laboratory. Currently, the application of powerful research methods for genetic analysis, including the polymerase chain reaction (PCR), DNA sequencing, and gene expression profiling using fluorescence microarrays, are not widely used in hospitals and extended-care units due to high-cost, long detection times, and extensive sample preparation. Bioassays, especially chip-based electrochemical sensors, may be suitable for the next generation of rapid, sensitive, and multiplexed detection tools. Herein, we report three different microelectrode platforms with capabilities enabled by nano- and microtechnology: nanoelectrode ensembles (NEEs), nanostructured microelectrodes (NMEs), and hierarchical nanostructured microelectrodes (HNMEs), all of which are able to directly detect unpurified RNA in clinical samples without enzymatic amplification. Biomarkers that are cancer and infectious disease relevant to clinical medicine were chosen to be the targets. Markers were successfully detected with clinically-relevant sensitivity. Using peptide nucleic acids (PNAs) as probes and an electrocatalytic reporter system, NEEs were able to detect prostate cancer-related gene fusions in tumor tissue samples with 100 ng of RNA. The development of NMEs improved the sensitivity of the assay further to 10 aM of DNA target, and multiplexed detection of RNA sequences of different prostate cancer-related gene fusion types was achieved on the chip-based NMEs platform. An HNMEs chip integrated with a bacterial lysis device was able to detect as few as 25 cfu bacteria in 30 minutes and monitor the detection in real time. Bacterial detection could also be performed in neat urine samples. The development of these versatile clinical diagnostic tools could be extended to the detection of various cancers, genetic, and infectious diseases.
author2 Kelley, Shana O.
author_facet Kelley, Shana O.
Fang, Zhichao
author Fang, Zhichao
author_sort Fang, Zhichao
title Chip-based Sensors for Disease Diagnosis
title_short Chip-based Sensors for Disease Diagnosis
title_full Chip-based Sensors for Disease Diagnosis
title_fullStr Chip-based Sensors for Disease Diagnosis
title_full_unstemmed Chip-based Sensors for Disease Diagnosis
title_sort chip-based sensors for disease diagnosis
publishDate 2010
url http://hdl.handle.net/1807/32039
work_keys_str_mv AT fangzhichao chipbasedsensorsfordiseasediagnosis
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