Novel biosensor can detect typhoid bacteria instantly

September 10, 2009 By Leave a Comment

Washington, Sept 9 (ANI): Scientists from Rovira i Virgili University (URV) in Tarragona have come up with a novel biosensor that can instantly detect Salmonella typhi, the bacteria that causes typhoid fever.

The technique uses carbon nanotubes and synthetic DNA fragments that activate an electric signal when they link up with the pathogen.

“We have developed a new biosensor that can detect extremely low concentrations of bacteria immediately, easily and reliably”, F. Xavier Rius, lead author of the study and a professor in the Chemometrics, Qualimetrics and Nanosensors research group in the Analytical Chemistry and Organic Chemistry Department of the URV, told SINC.

The new biosensor functions using a method, which involves carbon nanotubes with inbuilt aptamers providing electrochemical readings.

According to the researchers, the aptamers are small fragments of artificial DNA or RNA designed to attach themselves specifically to a particular molecule, cell or micro organism, in this case Salmonella.

If the bacteria are not present, the aptamers remain on the walls of the carbon nanotubes.

However, if they detect bacteria, they become activated and stick to it, and the carbon nanotubes generate an electric signal that is picked up by a simple potentiometer connected to the biosensor.

“The presence of the bacteria sparks a change in the interaction between the aptamers and the nanotubes, which takes place in a few seconds and creates an increase in the voltage of the electrode”, said Ruis, who led the research along with researcher Jordi Riu.

“This technique means small quantities of micro organisms can be detected simply and practically in real time, just the same as measuring the pH of water”, Ruis added.

The study appears in the scientific journal Angewandte Chemie International Edition. (ANI)

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New ultrasensitive electronic sensor to speed up DNA testing (corrected)

September 1, 2009 By Leave a Comment

Washington, Sept 1 (ANI): Singapore scientists have developed a new ultrasensitive electronic sensor that would speed up DNA testing for disease diagnosis and biological research.

The novel electronic sensor array would be rapid, accurate and cost-efficient.

According to lead researcher Dr Zhiqiang Gao, from Singapore’s Institute of Bioengineering and Nanotechnology (IBN), the Nanogap Sensor Array has shown “excellent” sensitivity at detecting trace amounts of DNA.

“By saving time and lowering expenses, our newly developed Nanogap Sensor Array offers a scalable and viable alternative for DNA testing,” said Gao.

The biosensor translates the presence of DNA into an electrical signal for computer analysis.

The distinctively designed sensor chip has the ability to detect DNA more efficiently by “sandwiching” the DNA strands between the two different surfaces.

“The novel vertical nanostructure design and two different surfaces of the sensor allow ultrasensitive detection of DNA,” said Gao.

“This sensitivity is best-in-class among electrical DNA biosensors. The design of the sensor also took into consideration the feasibility of mass production in a cost-effective way for expanded usage,” the expert added.

Presently, human DNA is detected through the use of polymerase chain reaction (PCR), which while effective, is also expensive, cumbersome and time-consuming for widespread use.

Although effective, tests involving PCR may not be optimal for situations such as a pandemic outbreak.

The biosensor captures DNA strands more effectively. This is possible because the two surfaces of the sensor are coated with a chemically treated “capture probe” solution through an electrochemical technique specially developed by IBN.

This allows DNA strands to “stick” more easily to the sensor, resulting in a faster and more accurate analysis.

“This new biosensor holds significant promise to speed up on-going efforts in the detection and diagnosis of debilitating diseases such as cancer, cardiovascular problems and infectious viruses,” said Dr Jackie Y. Ying, Executive Director of IBN, one of the research institutes of Singapore’s Agency for Science, Technology and Research (A*STAR).

“We aim to make healthcare accessible to the masses with early disease diagnosis as the critical driving force behind the research we undertake here at IBN,” she added.

The study appears in Journal of the American Chemical Society. (ANI)

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Inkjet printer technology may be used to make toxin-detecting biosensors

July 14, 2009 By Leave a Comment

Washington, July 14 (ANI): Soon, technology that is used to make office inkjet printers may be used to develop paper-based biosensors that can detect certain harmful toxins that can cause food poisoning or be used as bioterrorism agents.

In a research, John Brennan and his research team at McMaster University, working with the Sentinel Bioactive Paper Network, describe a method for printing a toxin-detecting biosensor on paper using a FujiFilm Dimatix Materials Printer.

The researchers demonstrated the concept on the detection of acetylcholinesterase (AChE) inhibitors such as paraoxon and aflatoxin B1 on paper using a “lateral flow” sensing approach similar to that used in a home pregnancy test strip.

The process involves formulating an ink like the one found in computer printer cartridges but with special additives to make the ink biocompatible.

An ink comprised of biocompatible silica nanoparticles is first deposited on paper, followed by a second ink containing the enzyme, and the resulting bio-ink forms a thin film of enzyme that is entrapped in the silica on paper.

When the enzyme is exposed to a toxin, reporter molecules in the ink change colour in a manner that is dependent on the concentration of the toxin in the sample.

This simple and cost-effective method of adhering biochemical reagents to paper is expected to bring the concept of bioactive paper a significant step closer to commercialization.

The goal for bioactive paper is to provide a rapid, portable, disposable and inexpensive way of detecting harmful substances, including toxins, pathogens and viruses, without the need for sophisticated instrumentation.

The research showed that the printed enzyme retains full activity for at least two months when stored properly, suggesting that such sensor strips should have a good shelf life.

Portable bio-sensing papers are expected to be extremely useful in monitoring environmental and food-based toxins, as well as in remote settings in less industrialized countries where simple bioassays are essential for the first stages of detecting disease.

Applications for bioactive paper also include clinical applications in neuroscience, drug assessment, and pharmaceutical development. (ANI)

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