Creating anticancer nanomaterials by simulating underwater volcanic conditions

Making nanoclusters of zinc peroxide in an environmentally friendly manner

16-May-2017 - Finland

Researchers at Aalto University, Finland, have developed anticancer nanomaterials by simulating the volcano-induced dynamic chemistry of the deep ocean. The novel method enables making nanoclusters of zinc peroxide in an environmentally friendly manner, without the use of additional chemicals. The as-synthesised zinc peroxide nanoparticles can be used as a tool for cancer therapy and against other complicated diseases.

Aalto University / Mikko Raskinen

Leidenfrost effect makes water droplets on a hot plate hover over the surface instead of making physical contact with it.

Aalto University

Anticancer nanomaterials erupt to the surface. Leidenfrost effect makes the molecules in the liquid above behave in an exceptional way.

Aalto University / Mikko Raskinen
Aalto University

The researchers have created these size-tailored nanoclusters by making use of the Leidenfrost effect. It is an event commonly observed in the kitchen while cooking. If you drop some water on a hot plate, droplets hover over the surface instead of making physical contact with it. In the Leidenfrost effect, a liquid close to an object much hotter than the liquid's boiling point produces an insulating vapour layer, preventing the liquid from boiling rapidly. Near volcano gates deep in the ocean or under special conditions in the lab, the vapour layer can cover a large area without rising away from the surface, while making the molecules in the liquid above behave in an exceptional way.

'The dynamic underwater chemistry seen in nature is inspiring for the next generation of eco-friendly nanochemistry. In this context, green synthesis of size-tailored nanoparticles in a facile and scalable manner via a dynamic process has not been introduced so far', tells Professor Mady Elbahri at Aalto University.

'We demonstrate the Leidenfrost dynamic chemistry occurring in an underwater overheated confined zone as a new tool for customised creation of nanoclusters of zinc peroxide. The hydrodynamic nature of the phenomenon ensures eruption of the nanoclusters towards a much colder region, giving rise to growth of monodisperse, size-tailored nanoclusters', continues Elbahri.

'Our study can pave the way for sustainable synthesis of monodispersed particles', explains Ramzy Abdelaziz, a postdoctoral researcher at Elbahri's group and coauthor of the study.

From a biomedical perspective, peroxides act as an oxygen supplier and thus can be exploited in treatment of a wide variety of diseases induced by anaerobic and even cancerous cells.

'Our nanoparticles have been investigated in terms of cytotoxic effect on suspension and adherent cells to prove their applicability as cancer nanotherapeutics', says Duygu Disci-Zayed, a former research group member.

Having synthesised the monodispersed ZnO2 particles, the researchers performed a series of initial experiments to determine the impact of these nanoparticles on the cancer, and normal, healthy cells. According to their study, ZnO2 nanoparticles have the potential to kill tumor cells by apoptotic and non-apoptotic mechanisms.

Original publication

Other news from the department science

These products might interest you

Eclipse

Eclipse by Wyatt Technology

FFF-MALS system for separation and characterization of macromolecules and nanoparticles

The latest and most innovative FFF system designed for highest usability, robustness and data quality

DynaPro Plate Reader III

DynaPro Plate Reader III by Wyatt Technology

Screening of biopharmaceuticals and proteins with high-throughput dynamic light scattering (DLS)

Efficiently characterize your sample quality and stability from lead discovery to quality control

particle analyzers
Loading...

More news from our other portals

So close that even
molecules turn red...