Spider silk: Mother Nature鈥檚 Bio-Superlens

A Golder web spider (Nephila edulis) on its web.A Golder web spider (Nephila edulis) on its web.Scientists at the UK鈥檚 Bangor and Oxford universities have achieved a world first: using spider-silk as a superlens to increase the microscope鈥檚 potential.

Extending the limit of classical microscope鈥檚 resolution has been the 鈥楨l Dorado鈥 or 鈥楬oly Grail鈥 of microscopy for over a century. Physical laws of light make it impossible to view objects smaller than 200 nm 鈥 the smallest size of bacteria, using a normal microscope alone. However, superlenses which enable us to see beyond the current magnification have been the goal since the turn of the millennium.

Hot on the heels of a paper (,2016) revealing that a team at 麻豆传媒高清版鈥檚 School of Electronic Engineering has used a nanobead-derived superlens to break the perceived resolution barrier, the same team has achieved another world first.

Now the team, led by Dr Zengbo Wang and in colloboration with Prof. Fritz Vollrath鈥檚 silk group at Oxford University鈥檚 Department of Zoology, has used a naturally occurring material 鈥 dragline silk of the golden web spider, as an additional superlens, applied to the surface of the material to be viewed, to provide an additional 2-3 times magnification.

SEM image of Blu-ray disk with 200/100 nm groove and lines (detail). SEM image of Blu-ray disk with 200/100 nm groove and lines (detail).This is the first time that a naturally occurring biological material has been used as a superlens.

In the paper in Nano Letters (, Aug 17 2016), the joint team reveals how they used a cylindrical piece of spider silk from the thumb sized Nephila spider as a lens.

Dr Zengbo Wang said:

鈥淲e have proved that the resolution barrier of microscope can be broken using a superlens, but production of manufactured superlenses invovles some complex engineering processes which are not widely accessible to other reserchers. This is why we have been interested in looking for naturally occurring superlenses provided by 鈥楳other Nature鈥, which may exist around us, so that everyone can access superlenses.鈥

Prof Fritz Vollrath adds:

鈥淚t is very exciting to find yet another cutting edge and totally novel use for a spider silk, which we have been studying for over two decades in my laboratory.鈥

These lenses could be used for seeing and viewing previously 鈥榠nvisible鈥 structures, including engineered nano-structures and biological micro-structures as well as, potentially, native germs and viruses.

Clear magnified image (2.1x) of Blu-ray disk under spider silk superlens (detail). Clear magnified image (2.1x) of Blu-ray disk under spider silk superlens (detail). The natural cylindrical structure at a micron- and submicron-scale make silks ideal candidates, in this case, the individual filaments had diameters of one tenth of a thin human hair.

The spider filament enabled the group to view details on a micro-chip and a blue- ray disk which would be invisible using the unmodified optical microscope.

In much the same was as when you look through a cylindrical glass or bottle, the clearest image only runs along the narrow strip directly opposite your line of vision, or resting on the surface being viewed, the single filament provides a one dimensional viewing image along its length.

Wang explains:

鈥淭he cylindrical silk lens has advantages in the larger field-of-view when compared to a microsphere superlens. Importantly for potential commercial applications, a spider silk nanoscope would be robust and economical, which in turn could provide excellent manufacturing platforms for a wide range of applications.鈥

James Monks, a co-author on the paper comments: 鈥渋t has been an exciting time to be able to develop this project as part of my honours degree in electronic engineering at 麻豆传媒高清版 and I am now very much looking forward to joining Dr Wang鈥檚 team as a PhD student in nano-photonics.鈥

Publication date: 19 August 2016