A method for directing therapeutic nanoparticle-labeled cells to selected locations within the body and/or for retaining therapeutic nanoparticle-labeled cells at selected locations within the body, the method comprising: providing an article comprising a body of material configured to be secured about the body of a patient and having a plurality of pockets thereon, wherein each pocket is sized to receive and retain one or more magnets therein; injecting therapeutic USPIO nanoparticle-containing cells into a target therapy site; securing the article to the body of the patient; and inserting at least one magnet into at least one pocket so as to provide a desired magnetic field for further directing therapeutic nanoparticle-labelled cells to a target therapy site and/or for retaining therapeutic nanoparticle-labeled cells at the target therapy site.

A method for real-time, high-density physiological data collection includes automatically measuring, by a wearable device, one or more physiological parameters during each of a plurality of measurement periods, and upon conclusion of a measurement period, for each of the plurality of measurement periods, automatically transmitting by the wearable device data representative of the physiological parameters measured during that measurement period, to a server, the server configured to develop a baseline profile based on the data transmitted by the wearable device for the plurality of measurement periods. The measurement periods may extend through a plurality of consecutive days, and each of the consecutive days may include multiple measurement periods. At least some of the physiological parameters are measured by non-invasively detecting one or more analytes in blood circulating in subsurface vasculature proximate to the wearable device.

Methods and devices are disclosed for the non-invasive treatment of autoimmune diseases or disorders through the delivery of energy to target nervous tissue, particularly the vagus nerve.. A device for treating an autoimmune disease or disorder comprises one or more electrodes having a contact surface configured for contacting an anterior portion of an outer skin surface of a neck of a patient and an energy source coupled to the electrodes. The energy source is configured to generate one or more electrical impulses and to transmit the electrical impulses to the electrodes and transcutaneously through the anterior portion of the outer skin surface of the neck of the patient at or near a vagus nerve. The electrical impulses are sufficient to modulate the vagus nerve and to inhibit inflammation and treat the disorder.

The present invention provides, among other things, apparatus and methods of use for treating a subject in need of assistance with breathing. In some embodiments the subject suffers from airflow obstruction. In some embodiments, the subject suffers from chronic obstructive pulmonary disease.

A system and method for performing surgical procedures within a body cavity, e.g. abdomen, uses a magnetized device is utilized to allow a surgeon to control intra-abdominal organs and objects. The system and method allows a surgeon to perform an intra-abdominal procedure without the need to position surgical tools inside of the body cavity. Additional surgical ports are not necessary as the magnetized device allows the surgeon to retract or position various objects within the abdomen.

A ventilation arrangement (1) comprises an induction device (2) and a control unit (3). The induction device (2) has an electro-magnetic field generator (21) with a coil design (211) configured to generate a spatial electro-magnetic field having a targeted shape. The control unit (3) is in communication with the induction device (2) and configured to control the induction device (2) to generate the electro-magnetic field. The electro-magnetic field generator (21) of the induction device (2) is configured to be positioned at a human or animal patient (5) such that, for activating a diaphragm of the patient (5), a Phrenic nerve of the patient (5) is stimulatable by the spatial electro-magnetic field generated by the coil design (211). The control unit (3) is connectable to a ventilation machine (6) to receive ventilation data about a ventilation of the patient (5). The control unit (3) is configured to evaluate the ventilation data and to operate the induction device (2) in accordance with the evaluated ventilation data.

A stimulation device includes a body containing at least one stimulation means adapted to be transcutaneously attached to the neck of a subject. The stimulation means is adapted to generate a stimulating signal during a stimulating state. The stimulation means is positioned to be in stimulating contact with the sternocleidomastoid muscle and the trunks of the lesser occipital nerve, greater auricular nerve, transverse cervical nerve or supraclavicular nerve with their autonomic fibers synchronously. The stimulation can be provided in the form an electrical, optical, vibrational, thermal, mechanical and/or magnetic stimulation. The stimulation device can be used bilaterally on the right and left sides of the subject's neck, working as a system in a synchronous or alternating manner.

One embodiment provides a method for controlling a microagent in a workspace. The method includes providing a plurality of magnetic sources and generating a rotating gradient magnetic field by activating the plurality of magnetic sources differently such that a driving force is created to drive the microagent towards an aggregation center in the workspace.

Devices and methods for tissue treatment produce a mechanical stimulation therapy and electromagnetic field therapy. The mechanical stimulation therapy provides stimulation of blood circulation and stimulates treated cells. The electromagnetic field enables thermal treatment of tissue. Combination of both therapies improves soft tissue treatment, mainly connective tissue in the skin area and fat reduction.

An incubator-actuator device including a sample chamber, a magnetic field generating coil, and a light-emitting diode (LED) placement cage is provided herein. The incubator-actuator device is configured for simultaneous optical irradiation and oscillating magnetic field irradiation of a mammalian cell or a nanostructure. A system including an incubator-actuator device including a sample chamber, a magnetic field generating coil, and a light-emitting diode (LED) placement cage, and a laser is also provided herein. The system is configured for simultaneous optical irradiation and oscillating magnetic field irradiation of a target.