IISc scientists develop novel technique to encapsulate liquid droplets used for various applications

IISc scientists have developed a new capillary force-assisted cloaking method to trap droplets within colloidal particles and liquid-infused surfaces. Droplets are used for various applications, such as in microreactors, drug delivery systems, in single crystal growth and cell culture platforms.

Scientists at the Indian Institute of Science (IISc) have developed a novel technique to encapsulate liquid droplets used for various applications, including single crystal growth and cell culture.

“The technique exploits the capillary effect — the rise of a liquid through a narrow space — to coat droplets in a composite shell containing oil-loving and hydrophobic particles. It offers the ability to tune the shell thickness over a wide range, allowing the encapsulation of droplets of different sizes,” said IISc.

The study was published in Nature Communications.

Droplets are important in a variety of fields. “In microreactors, droplets can be used to create different reaction environments or mix different chemicals. In drug delivery systems, droplets can be used to deliver drugs or other agents to specific tissues or organs. In crystallisation studies, droplets can be used to control the growth of crystals. And in cell culture platforms, droplets can be used to grow cells in a controlled environment, which can help to improve cell viability and proliferation,” said lead researcher Rutvik Lathia, a PhD student at the Centre for Nano Science and Engineering (CeNSE), IISc.

However, there are several challenges in using such droplets. They are vulnerable to contamination from the ambient environment, the ease and success of a particular process depends a lot on the surface they’re dropped on, and they can vanish into thin air pretty fast. While encapsulating droplets with liquids or solids that don’t mix with the droplets (like water droplets inside an oil shell) is a plausible solution to avoid these issues, making a shell that is hardy, continuous and has an adjustable thickness at a super tiny scale has proven elusive so far.

To address these challenges, Prosenjit Sen, Associate Professor at CeNSE, and his team have developed a new capillary force-assisted cloaking method to trap droplets within colloidal particles and liquid-infused surfaces.