Acoustofluidic technologies utilize acoustic waves to manipulate fluids and particles within
fluids, all in a contact-free and biocompatible manner. Over the past decade, acoustofluidic …

The high throughput deposition of microscale objects with precise spatial arrangement
represents a key step in microfabrication technology. This can be done by creating physical …

Acoustofluidics offers contact-free manipulation of particles and fluids, enabling their uses in
various life sciences, such as for biological and medical applications. Recently, there have …

A surge of research in intracellular delivery technologies is underway with the increased
innovations in cell‐based therapies and cell reprogramming. Particularly, physical cell …

Sonoporation is the process of transient pore formation in the cell membrane triggered by
ultrasound (US). Numerous studies have provided us with firm evidence that sonoporation …

Acoustofluidic platforms have great potentials to integrate capillary tubes for controlling and
manipulating microparticles and biological cells in both non-flowing and continuous-flow …

Exploiting acoustic streaming effects for microfluidic devices has been proven to be
important for cell, microparticle and fluid manipulation in many fields such as, biomedical …

Abstract Surface Acoustic Wave (SAW) based microfluidic devices provide active techniques
to manipulate fluid and particles, which can be used for precise and controllable patterning …

Acoustic-based microfluidics has been widely used in recent years for fundamental research
due to its simple device design, biocompatibility, and contactless operation. In this article …

Acoustic radiation torque (ART) plays an important role in the subject of acoustophoresis,
which could induce the spinning rotation of particles on their own axes. The partial wave …