Devices and methods are provided for administering a drug to a biological tissue in a patient, such as by intracellular and/or dermal delivery. The device includes a piezoelectric pulse generator; and an array of microneedle electrodes electrically coupled to the piezoelectric pulse generator, wherein the device, following insertion of the microneedle electrodes into the biological tissue, is configured to generate and deliver one or more electrical pulses through the microneedle electrodes effective to electroporate cells in the biological tissue and enable delivery of a drug into the electroporated cells.

Methods and apparatuses for treating inflammatory diseases by neurostimulation in patients who have failed to adequately respond or have become intolerant to a drug therapy (such as a TNF inhibitor and/or a JAK inhibitor).

Transfer of genetic and other materials to cells is conducted in a hands-free, automated and continuous process that includes flowing the cells between electroporation electrodes to facilitate delivery of a payload into the cells, while acoustophoretically focusing the cells. Also described is a control method for the acoustophoretic focusing of cells that includes detecting locations of cells flowing through a channel, such as with an image analytics system, and modulating a drive signal to an acoustic transducer to change the locations of the cells flowing in the channel. Finally, an electroporation driver module is described that uses a digital to analog converter for generating an electroporation waveform and an amplifier for amplifying the electroporation waveform for application to electroporation electrodes.

A ratio of reversible electroporation and irreversible electroporation may be controlled by selecting a symmetric waveform or asymmetric waveform to either minimize or enhance irreversible effects on cells in the target tissue. Combined reversible and irreversible electroporation includes inserting one or more therapeutic electrodes into a target tissue, introducing an electroporation compound into the target tissue, selecting a pulse waveform that is either 1) asymmetric bipolar that has positive and negative pulses with different durations, or 2) symmetric bipolar that has positive and negative pulses with the same duration, and delivering to the target tissue a series of electrical pulses having the selected pulse waveform.

A skin treatment device is provided, which includes a needle frame in which a front end outlet of a needle that penetrates an inside thereof projects toward a front thereof, a rear end inlet of the needle is open to an outside of a rear surface thereof, and a stepped partition wall is provided in a closed shape on the outside of the rear surface thereof; a needle cover having a space portion formed on a rear thereof toward an inside thereof, a needle guide portion formed on a front surface thereof; a contact PCB configured to receive a power that is supplied from a power supply device; and a needle hub having an insertion portion formed in a front thereof toward an inside thereof.

Cystic lesions can be treated by electroporation. For example, this document describes methods and devices for endoscopic ultrasound-guided ablation of cystic lesions using a needle for electroporation.

Methods and apparatus are provided for intravascularly-induced neuromodulation using a pulsed electric field, e.g., to effectuate irreversible electroporation or electrofusion, necrosis and/or inducement of apoptosis, alteration of gene expression, changes in cytokine upregulation, etc., in target neural fibers. In some embodiments, the intravascular PEF system comprises a catheter having a pair of bipolar electrodes for delivering the PEF, with a first electrode positioned on a first side of an impedance-altering element and a second electrode positioned on an opposing side of the impedance-altering element. A length of the electrodes, as well as a separation distance between the first and second electrodes, may be specified such that, with the impedance-altering element deployed in a manner that locally increases impedance within a patient's vessel, e.g., with the impedance-altering element deployed into contact with the vessel wall at a treatment site within the patient's vasculature, a magnitude of applied voltage delivered across the bipolar electrodes necessary to achieve desired neuromodulation is reduced relative to an intravascular PEF system having similarly spaced electrodes but no (or an undeployed) impedance-altering element. In a preferred embodiment, the impedance-altering element comprises an inflatable balloon configured to locally increase impedance within a patient's vasculature. The methods and apparatus of the present invention may be used to modulate a neural fiber that contributes to renal function.

A method for delivery of oral iontophoretic or reverse-iontophoretic effect by electrical current in combination with electrokinetic elements (e.g., ions, charged molecule(s) (such as a medication or a bioactive agent), and/or charged molecular complexes that may include uncharged molecules), the electrical current causing a motive force on such elements to and from biological tissues and fluids.

A system and method for selectively treating aberrant cells such as cancer cells through administration of a train of electrical pulses is described. The pulse length and delay between successive pulses is optimized to produce effects on intracellular membrane potentials. Therapies based on the system and method produce two treatment zones: an ablation zone surrounding the electrodes within which aberrant cells are non-selectively killed and a selective treatment zone surrounding the ablation zone within which target cells are selectively killed through effects on intracellular membrane potentials. As a result, infiltrating tumor cells within a tumor margin can be effectively treated while sparing healthy tissue. The system and method are useful for treating various cancers in which solid tumors form and have a chance of recurrence from microscopic disease surrounding the tumor.

Electroporation devices and methods of making the same. An electroporation device includes a plurality of independently controllable or addressable electrode pairs, a plurality of reaction chambers, each reaction chamber including a first chamber, a second chamber and a porous substrate separating the first chamber from the second chamber, and each reaction chambers being disposed between one of the plurality of independently controllable or addressable electrode pairs, a plurality of first microfluidic channels configured to deliver a cargo solution from a cargo inlet port to the plurality of first chambers, and a plurality of second microfluidic channels configured to deliver a cell culture from a cell inlet port to the plurality of second chambers. In operation, application of a voltage to an electrode pair permeabilizes the membranes of the cells adhered to the porous substrate in the reaction chamber disposed between the electrode pair.