Abstract: Provided herein are implantable biomaterials for promoting regeneration of an injured biological tissue, the biomaterials including piezoelectric materials and an extracellular matrix specific to the injured biological tissue, wherein the piezoelectric materials and the extracellular matrix are electrospun together to provide tissue-specific bioactive piezoelectric nanofiber scaffolds. Also provided herein are methods of fabricating a tissue-specific bioactive piezoelectric nanofiber scaffold and methods of promoting regeneration of injured biological tissue by implanting the disclosed bioactive piezoelectric scaffolds.

Abstract: Devices and methods for capturing biological materials using a potential well. An electrical signal is applied across a nanopipette having one end in a back-fill chamber and another end in a collection chamber containing a suspending medium including one or more types of particles. The collection end of the nanopipette includes a tip having an opening. The electrical signal applied across the nanopipette is configured to generate the potential well proximate to the tip in which the electrokinetic forces acting on the particles are balanced. The potential well may be configured to selectively trap one or the other types of particles suspended in the suspending medium. The particles may be transferred to a sample collection medium by immersing the tip in the sample collection medium and reversing the polarity of the electrical signal.

Abstract: A method of characterizing nanovesicles is disclosed. The method involves entrapping nanovesicles such as exosomes and sensing the dielectric properties of the exosomes using an electrical impedance sensing device. The method can distinguish exosomes based on different membrane compositions, different cellular origins, different size distribution and/or different cytosolic compositions.

Abstract: Devices and methods for capturing biological materials using a potential well. An electrical signal is applied across a nanopipette having one end in a back-fill chamber and another end in a collection chamber containing a suspending medium including one or more types of particles. The collection end of the nanopipette includes a tip having an opening. The electrical signal applied across the nanopipette is configured to generate the potential well proximate to the tip in which the electrokinetic forces acting on the particles are balanced. The potential well may be configured to selectively trap one or the other types of particles suspended in the suspending medium. The particles may be transferred to a sample collection medium by immersing the tip in the sample collection medium and reversing the polarity of the electrical signal.