We use cookies to understand how you use our site and to improve your experience. This includes personalizing content and advertising. To learn more, click here. By continuing to use our site, you accept our use of cookies. Cookie Policy.

Features Partner Sites Information LinkXpress hp
Sign In
Advertise with Us
INTEGRA BIOSCIENCES AG

Download Mobile App




Biosensing Platform Diagnoses Diseases Through Single Molecule Detection

By LabMedica International staff writers
Posted on 15 Sep 2020
A new diagnostic approach employs a DNA origami biosensor platform coupled with a nanopore read-out that enables individual biomarker detection.

The ability to detect low concentrations of biomarkers in patient samples is one of the cornerstones of modern healthcare. More...
In general, biosensing approaches are based on measuring signals resulting from the interaction of a large ensemble of molecules with the sensor. To increase the sensitivity of this approach, investigators at the University of Leeds (United Kingdom) developed a biosensor platform using DNA origami, which featured a central cavity with a target-specific DNA aptamer coupled with a nanopore read-out to enable individual biomarker detection.

DNA origami is the nanoscale folding of DNA to create non-arbitrary two- and three-dimensional nanoscale shapes. The current method of DNA origami involves the folding of a long single strand of viral DNA aided by multiple smaller "staple" strands. These shorter strands bind the longer in various places, resulting in the formation of a pre-defined two- or three-dimensional shape.

Aptamers are nucleic acid species that have been engineered through repeated rounds of in vitro selection to bind to various molecular targets such as small molecules, proteins, nucleic acids, and even cells, tissues, and organisms. Aptamers are useful in biotechnological and therapeutic applications as they offer molecular recognition properties that rival that of antibodies. In addition to their discriminate recognition, aptamers offer advantages over antibodies as they can be engineered completely in a test tube, are readily produced by chemical synthesis, possess desirable storage properties, and elicit little or no immunogenicity in therapeutic applications.

The University of Leeds investigators demonstrated that DNA aptamer-functionalized DNA origami could capture an analyte of interest, and that the occupied and unoccupied DNA origami’s translocation fingerprints were readily distinguishable. In this study, they revealed a biosensing platform with a three nanomolar limit of detection, which was capable of detecting human C-reactive protein (CRP) in clinically relevant fluids.

The investigators reported that in addition to the characteristically different peak shape, also the peak amplitude, and dwell time could be used to distinguish occupied from unoccupied carriers. The read-out was entirely electrical so it could be miniaturized, enabling point-of-care detection. Taken together, this enabled quantitative biosensing via counting of individual occupied DNA origami carriers, which was demonstrated in physiological solutions and diluted human plasma.

First author, Dr. Mukhil Raveendran, a researcher at the University of Leeds, said, "One of the main advantages is the minimal sample needed. We are able to isolate individual molecules from small samples to identify specific illnesses. The process is very quick, and takes just minutes to provide results. The captured biomarkers are then read with nanopores and we can do this one molecule at a time. By coupling DNA origami and nanopores we are able to quantitatively detect disease biomarkers with single molecule sensitivity."

The DNA origami-nanopore biosensing platform was described in the September 1, 2020, online edition of the journal Nature Communications.

Related Links:
University of Leeds


Platinum Member
Xylazine Immunoassay Test
Xylazine ELISA
Verification Panels for Assay Development & QC
Seroconversion Panels
Anti-Cyclic Citrullinated Peptide Test
GPP-100 Anti-CCP Kit
Gold Member
Automatic Western Blot Analyzer
Tenfly Phoenix Blot Analyzer
Read the full article by registering today, it's FREE! It's Free!
Register now for FREE to LabMedica.com and get access to news and events that shape the world of Clinical Laboratory Medicine.
  • Free digital version edition of LabMedica International sent by email on regular basis
  • Free print version of LabMedica International magazine (available only outside USA and Canada).
  • Free and unlimited access to back issues of LabMedica International in digital format
  • Free LabMedica International Newsletter sent every week containing the latest news
  • Free breaking news sent via email
  • Free access to Events Calendar
  • Free access to LinkXpress new product services
  • REGISTRATION IS FREE AND EASY!
Click here to Register








Channels

Clinical Chemistry

view channel
Image: QIP-MS could predict and detect myeloma relapse earlier compared to currently used techniques (Photo courtesy of Adobe Stock)

Mass Spectrometry-Based Monitoring Technique to Predict and Identify Early Myeloma Relapse

Myeloma, a type of cancer that affects the bone marrow, is currently incurable, though many patients can live for over 10 years after diagnosis. However, around 1 in 5 individuals with myeloma have a high-risk... Read more

Immunology

view channel
Image: The cancer stem cell test can accurately choose more effective treatments (Photo courtesy of University of Cincinnati)

Stem Cell Test Predicts Treatment Outcome for Patients with Platinum-Resistant Ovarian Cancer

Epithelial ovarian cancer frequently responds to chemotherapy initially, but eventually, the tumor develops resistance to the therapy, leading to regrowth. This resistance is partially due to the activation... Read more

Technology

view channel
Image: Ziyang Wang and Shengxi Huang have developed a tool that enables precise insights into viral proteins and brain disease markers (Photo courtesy of Jeff Fitlow/Rice University)

Light Signature Algorithm to Enable Faster and More Precise Medical Diagnoses

Every material or molecule interacts with light in a unique way, creating a distinct pattern, much like a fingerprint. Optical spectroscopy, which involves shining a laser on a material and observing how... Read more

Industry

view channel
Image: The collaboration aims to leverage Oxford Nanopore\'s sequencing platform and Cepheid\'s GeneXpert system to advance the field of sequencing for infectious diseases (Photo courtesy of Cepheid)

Cepheid and Oxford Nanopore Technologies Partner on Advancing Automated Sequencing-Based Solutions

Cepheid (Sunnyvale, CA, USA), a leading molecular diagnostics company, and Oxford Nanopore Technologies (Oxford, UK), the company behind a new generation of sequencing-based molecular analysis technologies,... Read more
Copyright © 2000-2026 Globetech Media. All rights reserved.