Tag Archives: Stephen D. Hudson

Mite silk as the basis for a new nanobiomaterial

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For the record, this is spider mite silk (I have many posts about spider silk and its possible applications on this blog; just search ‘spider silk’)..

The international collaborative team includes a Canadian university in combination with a Spanish university and a Serbian university. The composition of the team is one I haven’t seen here before. From a December 17, 2020 news item on phys.org (Note: A link has been removed),

An international team of researchers has developed a new nanomaterial from the silk produced by the Tetranychus lintearius mite. This nanomaterial has the ability to penetrate human cells without damaging them and, therefore, has “promising biomedical properties”.

The Nature Scientific Reports journal has published an article by an international scientific team led by Miodrag Grbiç, a researcher from the universities of La Rioja (Spain), Western Ontario (Canada) and Belgrade (Serbia), in its latest issue entitled “The silk of gorse spider mite Tetranychus lintearius represents a novel natural source of nanoparticles and biomaterials.”

In it, researchers from the Murcian Institute for Agricultural and Food Research and Development (IMIDA), the Barcelona Institute of Photonic Sciences, the University of Western Ontario (Canada), the University of Belgrade (Serbia) and the University of La Rioja describe the discovery and characterisation of this mite silk. They also demonstrate its great potential as a source of nanoparticles and biomaterials for medical and technological uses.

A December 17, 2020 Universidad de La Rioja press release (also on EurekAlert), which originated the news item, further explains the research,

The interest of this new material, which is more resistant than steel, ultra flexible, nano-sized, biodegradable, biocompatible and has an excellent ability to penetrate human cells without damaging them, lies in its natural character and its size (a thousand times smaller than human hair), which facilitates cell penetration.

These characteristics are ideal for use in pharmacology and biomedicine since it is biocompatible with organic tissues (stimulates cell proliferation without producing toxicity) and, in principle, biodegradable due to its protein structure (it does not produce residues).

Researcher Miodrag Grbi?, who heads the international group that has researched this mite silk, highlights “its enormous potential for biomedical applications, as thanks to its size it is able to easily penetrate both healthy and cancerous human cells”, which makes it ideal for transporting drugs in cancer therapies, as well as for the development of biosensors to detect pathogens and viruses.

THE ‘RIOJANO BUG’

Tetranychus lintearius is an endemic mite from the European Atlantic coast that feeds exclusively on gorse (Ulex europaeus). It is around 0.3 mm in size, making it smaller than the comma on a keyboard, while the strength of its silk is twice as high as standard spider silk.

It is a very rare species that has only been found so far in the municipality of Valgañón (La Rioja, Spain), in Sierra de la Demanda. It was located thanks to the collaboration of Rosario García, a botanist and former dean of the Faculty of Science and Technology at the University of La Rioja, which is why researchers call it “the Rioja bug” (“El Bicho Riojano”).

The resistance of the silk produced by Tetranychus lintearius is twice that of spider silk, a standard material used for this type of research, and stronger than steel. It also has advantages over the fibres secreted by the silkworm due to its higher Young’s modulus, its electrical charge and its smaller size. These characteristics, along with its lightness, make it a promising natural nanomaterial for technological uses.

This finding is the result of work carried out by the international group of researchers led by Miodrag Grbi?, who sequenced the genome of the red spider Tetranychus urticae in 2011, publishing the results in Nature: https://www.nature.com/articles/nature10640.

Unlike the red spider (Tetranychus urticae), the gorse mite (Tetranychus lintearius) produces a large amount of silk. It has been reared in the laboratories of the Department of Agriculture and Food of the University of La Rioja, under the care of Professor Ignacio Pérez Moreno, allowing research to continue. Red spider silk is difficult to handle and has a lower production rate.

Here’s a link to and a citation for the 2020 paper,

The silk of gorse spider mite Tetranychus lintearius represents a novel natural source of nanoparticles and biomaterials by Antonio Abel Lozano-Pérez, Ana Pagán, Vladimir Zhurov, Stephen D. Hudson, Jeffrey L. Hutter, Valerio Pruneri, Ignacio Pérez-Moreno, Vojislava Grbic’, José Luis Cenis, Miodrag Grbic’ & Salvador Aznar-Cervantes. Scientific Reports volume 10, Article number: 18471 (2020) DOI: https://doi.org/10.1038/s41598-020-74766-7 Published: 28 October 2020

This paper is open access.

Spider-mites spin new nanomaterial at Canada’s University of Western Ontario

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I’m not always the sharpest knife in the drawer and skimming news articles exacerbates the problem, so, it took me a minute (more or less) to realize that spiders and spider-mites are not the same, which is what makes this discovery about spider-mite silk, featured in a May 23, 2013 news item on phys.org, special in amongst the many stories on spider silk (Note: A link has been removed),

A new, natural nanomaterial, which may prove incredibly beneficial to medical bioengineers, has been discovered by the research team at Western University [aka University of Western Ontario] that successfully sequenced the spider mite genome in 2011.

Western biology professor Miodrag Grbic and his team have now collaborated with physicist Jeff Hutter to test – for the first-time ever – the durability of spider-mite silk and found the bionanomaterial, which is one thousand times thinner than human hair, to be a potentially superior alternative to spider silk, itself long considered a highly attractive light-weight biomaterial due to its high tensile strength and elasticity.

This is a very good video from Western University (aka University of Western Ontario) featuring both Grbić and Hutter describing their work,

The Western University Apr. 25, 2013 media release, which originated the news item on phys.org, echoes the content in the video,

“One of the discoveries spinning out from our sequencing of the spider-mite genome was spider-mite silk,” explains Grbic, regarding the findings published in Nature in 2011. “When we conceived this project, our idea was to develop tools to control this important world-wide pest but we didn’t even dream that we were going to discover a potential bionanomaterial naturally produced by the spider-mite.”

Due to the near infinitesimal size of the spider mite silk, traditional theories were irrelevant so Hutter and Steve Hudson from the Department of Physics & Astronomy were forced to rethink conventional methods used for measuring the mechanical properties of nanomaterials.

“Basically you measure the strength of a nanofibre by anchoring it at both ends, suspending it, and then bending it with an atomic force microscope,” explains Hutter. “These fibres were so thin that the conventional theory didn’t apply and we had to develop a new theory to understand the data.”

Hutter and Grbic are most excited that spider mite silk has proven to be a truly natural nanomaterial, making its practical applications numerous.

“Spider silk, which people often talk about, has similar properties but it doesn’t score quite as high on Young’s modulus,” says Hutter, explaining the scientific measure used to characterize stiffness in elastic materials. “Plus spider mite silk is way thinner.”

Grbic says potential applications would require further research but could include construction of scaffolding for cell growth, as well as tissue regeneration and transplantation.

Here’s a link to and citation for the team’s latest spider mite silk paper,

Measurement of the elastic modulus of spider mite silk fibers using atomic force microscopy
by Stephen D. Hudson, Vladimir Zhurov, Vojislava Grbić, Miodrag Grbić, and Jeffrey L. Hutter. J. Appl. Phys. 113, 154307 (2013); http://dx.doi.org/10.1063/1.4800865 (7 pages) Published online 16 April 2013

The paper is behind a paywall.