Novel Piezoelectric Device for Inducing Strain on Biological Tissue At High Speed

Abstract: A novel mechanically amplified piezoelectric device is presented that induces large complex strains on biological tissue at high speeds. This device allows for the mechanotransduction process (translation of mechanical forces into biochemical signalling) to be studied for different biological tissues, such as single-layered cultured cells on an elastomer membrane or mammalian tissue samples. Two compliant rhombus mechanical amplifiers in a nested configuration are used to overcome the common limitation of piez… Show more

“…Modern molecular-interface tools like optical tweezers, magnetic resonance imaging, and atomic force microscopy have greatly simplified the research of these complex systems [13]. Even though these techniques have important breakthroughs, they are time-consuming, have poor throughput and molecular selectivity, and are not easy to operate within the low pN range of force appropriate for most biological effects [14]. Another requirement is that the biomolecule be attached to long ropes or be operated near a surface.…”

Design and Optimization of Mechano transduction Sensors for effective analysis of proteins with Robotic interference

“…Modern molecular-interface tools like optical tweezers, magnetic resonance imaging, and atomic force microscopy have greatly simplified the research of these complex systems [13]. Even though these techniques have important breakthroughs, they are time-consuming, have poor throughput and molecular selectivity, and are not easy to operate within the low pN range of force appropriate for most biological effects [14]. Another requirement is that the biomolecule be attached to long ropes or be operated near a surface.…”

Design and Optimization of Mechano transduction Sensors for effective analysis of proteins with Robotic interference