Creating a new vision for multifunctional materials

Creating a new vision for multifunctional materials

Multifunctional materials with sensory capabilities like those of vision, touch or even smell could profoundly expand the possibilities of industrial design in many areas. Taking a cue from nature, a cross-institutional collaboration involving researchers from the Wyss Institute for Biologically Inspired Engineering at Harvard University and MIT has deciphered how the bio-mineral making up the body armour of a chiton mollusk has evolved to create functional eyes embedded in the animal’s protective shell

Wyss instituteThe findings could help determine so far still elusive rules for generating manmade multifunctional materials and are reported in the November 20 issue of Science.

Multifunctional materials that can sense physical stimuli in their environments could enable us to build houses that make use of their environments, to constantly monitor wear-and-tear and look for signs of damage in materials or even to better deliver some drugs and produce bioengineered organs.

“To date, artificial materials that have the ability to perform multiple and often structurally opposite functions are not available. We cannot yet rationally design them but studying different multifunctional biomaterials present in nature should ultimately allow us to deduct the key principles for this relatively new area of materials science,” said Joanna Aizenberg, Ph.D., who is a Core Faculty member at the Wyss Institute, leader of the Wyss Adaptive Material Technologies platform, and also is the Amy Smith Berylson Professor of Materials Science at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS). Early work by Aizenberg on a sea-dwelling brittlestar that uses the same mineralized material to grow both a skeleton and visual organs had set the stage for the exploration into multifunctional biomaterials.

Now, inspired by previous biological research, performed by Daniel Speiser, Ph.D., Aizenberg and Christine Ortiz, Ph.D., the Morris Cohen Professor of Materials Science and Engineering at MIT, these formed a multi-disciplinary team to study another tell the tale example offered by nature: the outer protective shell of the chiton Acanthopleura granulata, a tropical sea water mollusk, that is endowed with hundreds of tiny eyes. Speiser is a Professor at the University of South Carolina who joined the Harvard/MIT-led effort.

Most eyes in nature are made of organic molecules. In contrast, the chiton’s eyes are inorganic and made of the same crystalline mineral called aragonite that also assembles the body armour. They enable the chiton to perceive changes in light and thus to respond to approaching predators by tightening their grip to surfaces under water.

Using a suite of highly resolving microscopic and crystallographic techniques, the team unravelled the 3-dimensional architecture and geometry of the eyes, complete with an outer cornea, a lens and an underlying chamber that houses the photoreceptive cells necessary to feed focused images to the chiton’s nervous system. Importantly, the researchers found that aragonite crystals in the lens are larger than in the shell and organized into more regular alignments that allow light to be gathered and bundled.

Aragonite crystals in the chiton’s eyes are arranged into lenses that can collect light and focus it so that complete images of close objects such as predatory fish are formed and processed. Credit: Wyss Institute at Harvard University

“By studying isolated eyes, we identified how exactly the lens material generates a defined focal point within the chamber which, like a retina, can render images of objects such as predatory fish,” said Ling Li, a postdoctoral fellow working with Aizenberg and a co-first author of the study.

“We also learned that optical performance was developed as a second function to the otherwise protective shell with mutual trade-offs in both functionalities. The material properties that are favoured for optical performance are usually not favoured for mechanical robustness so that the evolving chiton had to balance out its mechanical vulnerabilities by limiting the size of the eyes and placing them in regions protected by strong protrusions,” said Li.

“The investigation of Nature’s finest ‘multitasking artists’ can provide insight into functional synergies and trade-offs in multifunctional materials and guide us in other studies toward the development of revolutionary biomimetic materials. We thus are probably one step closer to construct houses made of a material that is not only mechanically robust, but also furnished with lenses capable of flexibly regulating light and temperature inside and sense environmental conditions,” said Aizenberg.

“This study shows just how amazing nature is at solving complex problems in simple and elegant ways. By uncovering the design rules, it became evident that this simple organism uses to self-assemble a multi-functional shell that simultaneously provides physical protection from the environment and an eye that can sense oncoming invaders. The team is now in a position to leverage these insights to engineer synthetic materials that could lead to entirely new solutions for both industrial and medical applications,” said Wyss Institute Founding Director Don Ingber, M.D., Ph.D., who also is the Judah Folkman Professor of Vascular Biology at Harvard Medical School and Boston Children’s Hospital, and Professor of Bioengineering at SEAS.

The research team used the 2-BM beamline at the Advanced Photon Source (APS), a U.S. Department of Energy (DOE) Office of Science User Facility located at Argonne National Laboratory, to conduct high-resolution X-ray micro-tomography towards determining the 3-D morphology of the sensory structure in the shell of chitons.

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