A system for infusing medication into a mammalian subject is provided. The system includes an injection system for controlling a flow of fluid from a fluid reservoir to a needle. A sensor is provided that detects a characteristic indicative of the fluid pressure in the needle. The injection system controls the flow of fluid to the needle in response to the characteristic detected by the sensor and the sensor continuously detects the characteristic as the needle is inserted into the subject. The system further includes a conductive element for providing electric nerve stimulation, wherein the system provides electric nerve stimulation in response to the sensor detecting a pressure exceeding an upper limit.

Provided is a needle assembly including: a plurality of needles; a main body having a plurality of holes through which the plurality of needles pass in a first direction; and a fixing member coupled to the main body and having a plurality of fixed inclined surfaces supporting the plurality of needles.

A system is provided for stimulating renal nerves. The system includes an interstitial device to provide stimulation and denervation of the renal nerves from outside the renal artery. The interstitial device extends through non-vascular tissue and into a periarterial space. The system also includes a control unit in communication with the interstitial device, configured to: obtain, from a sensor, first information pertaining to a blood pressure or heart rate; stimulate, using one or more electrodes of the interstitial device, renal sympathetic nerves associated with the renal artery; and obtain, from the sensor, second information pertaining to the blood pressure or heart rate of the subject. Based on a difference between the first information and the second information, the control unit determines whether the subject is suitable for a sympathetic denervation procedure and causes the interstitial device to perform the sympathetic denervation procedure if the subject is suitable.

Stimulation using EA of LI-4, LI-11, GV-14 and GV-20 in humans, horses, and rodents results in mobilization of MSCs into systemic circulation. Methods are provided for increasing mesenchymal stem cells in the circulating blood of a mammal by contacting acupuncture points LI-4, LI-11, GV-14, and GV-20 of the mammal with a therapeutically effective amount of EA stimulation to mobilize MSCs into the circulating blood of the mammal. Methods for treating damaged tissue, specifically damaged tendons are also provided. Isolated mesenchymal stem cells made according to these methods, methods of isolated them, and stem cell banks that store them are also provided.

A dual chambered syringe includes: an inner barrel defining a first inner chamber, the inner barrel having an apertured stopper at its distal end, the inner barrel being open at its proximal end; a shaft adapted to fit within the inner barrel, the shaft having a distal end which is engageable with the aperture of the stopper; a device for controlling engaging and disengaging of the distal end of the shaft with the aperture of the stopper; an outer barrel concentric with the inner barrel defining a second inner chamber, the outer barrel having a distal end for receiving and dispensing fluids and a proximal end into which the distal end of the inner barrel is insertable into the second inner chamber; the apertured stopper engages the second inner chamber of the outer barrel and selectively prevents or permits the passage of fluids between the outer barrel second chamber and the inner barrel first chamber; the inner barrel having an engageable surface on its outside surface; and, the outer barrel having operatively associated therewith an engaging device for selective engagement and disengagement with the engageable surface on the inner barrel.

Improvements to intracardiac devices such as intracardiac blood pump assemblies, and associated methods. In one example, the present technology includes systems and methods for pacing the heart, and/or performing cardiac ablation using electrodes mounted on a portion of the intracardiac device. In another example, the present technology includes systems and methods for detecting mural thrombi in a patient's heart using electrical sensors or ultrasonic phased arrays mounted on the intracardiac device. In another example, the present technology includes systems and methods for detecting tissue changes and reactions in heart tissue during treatment using one or more temperature sensors. In another example, the present technology includes an improved distal tip for use with an intracardiac device. In another example, the present technology includes systems and methods for maintaining an intracardiac device in a desired position within a patient's heart using magnets or ultrasonic phased arrays mounted on the intracardiac device.

The present disclosure is directed to a portable system and method for modulating targeted neural and non-neural tissue of a nervous system to block nerve conduction for the treatment of pain. A high-efficiency portable electrical stimulation system is provided that allows a user to carry the system and move around freely while continuously receiving therapy. The electronic control system is configured to deliver high-frequency electrical stimulation at a therapeutic level, for an intended duration (e.g., up to 24 hours or more) at a manageable and/or comfortable weight for a person, to the target nerve.

A method of and apparatus for treating tissue wherein a handpiece with a cartridge of motor driven needles is placed in contact with tissue. The motor is energized to drive the needles. Energy is applied energy to the needles. Tissue impedance at the start of treatment is measured. Tissue impedance at the end of treatment is measured. The operator is then notified that corrective action is needed if the measured ending impedance is higher than the measured starting impedance indicating the needles are not inserted into the tissue.

An example of an apparatus for percutaneously delivering neurostimulation energy to a patient and sensing from the patient using a test device placed externally to the patient is provided. The apparatus may include a stimulation lead, a sensing reference electrode, a sensing wire, and a connection system. The stimulation lead may be configured to be percutaneously introduced into the patient to place the one or more electrodes in the patient. The sensing reference electrode may be configured to be placed in the patient. The sensing wire may be connected to the sensing reference electrode and configured to be percutaneously introduced into the patient to place the sensing reference electrode in the patient. The connection system may be configured to mate the lead connector and the wire connector and to provide electrical connections between the lead connector and the test device and between the wire connector and the test device.

Described herein are methods and systems for using the treatment tip apparatuses and high-voltage connectors with robotic surgical systems. For example, retractable treatment tip apparatuses (e.g., devices, systems, etc.) including one, or more preferably a plurality, of electrodes that are protected by a housing (which may be retractable) until pressed against the tissue for deployment of the electrodes and delivery of a therapeutic treatment, are disclosed. In particular, these apparatuses may include a plurality of treatment needle electrodes and may be configured for the delivery of nanosecond pulsed electric fields. Also described herein are high-voltage connectors configured to provide high-voltage energy, such as nsPEF pulses, from a generator to the retractable treatment tip apparatuses.