A treatment system includes a generator and a fluid transfer cartridge. The fluid transfer cartridge includes a cartridge shell defining a cartridge cavity between a front face and a rear face. The front face includes an opening, and the cartridge cavity is visibly exposed through the opening. The fluid transfer cartridge includes a syringe barrel disposed within the cartridge cavity, and a handle that extends from the front face over the opening. The syringe barrel can be visibly exposed on a side of the handle. Other embodiments are also described and claimed.

Relatively non-invasive devices and methods for heating or cooling a patient's body are disclosed. Devices and methods for treating ischemic conditions by inducing therapeutic hypothermia are disclosed. Devices and methods for inducing therapeutic hypothermia through esophageal cooling are disclosed. Devices and methods for operative temperature management are disclosed.

Devices, systems, and methods for applying pulsed energy to effectuate a physiological response in a human subject. Systems and methods disclosed herein can include, for example, a stimulus device that applies pulsed energy, such as heat, into a volume of tissue. The stimulus device can include one or more electrodes and can be affixed to the skin or implanted at a target site within the body. The systems and method can further include a monitoring device that detects at least one physiological parameter of the human subject during application of the pulsed energy, such as blood flow, oxygen delivery, muscle tension, subcutaneous or muscle temperatures, or brain activity. A control device can use the detected physiological parameter to define treatment parameters of the stimulus device such that the pulsed energy synchronizes with the measured physiological parameter to effectuate a desired response, such as reducing pain, suppressing appetite, and/or activating a hedonic response.

An intravenous heat exchange catheter and/or an external cooling pad/bladder can be used to maintain hypothermia in, e.g., a cardiac arrest patient, but to accelerate the cooling process the patient first can be infused with cold saline before the opportunity arises to connect the catheter or pad to the patient.

A stent device including a stent coated with a photosensitizer, the stent including a pair of electrodes; and a circuit fixed to the stent, the circuit including a light emitting diode, a power receiving means for wirelessly receiving power from the outside, and converting the power to electric power; a second communicating means for receiving a control command from the outside; and a second control means for applying, based on the control command, the electric power to the electrodes causing an electric current to flow through the stent between the electrodes, the flow causing heating of the stent, and for controlling a temperature of the stent to provide hyperthermia therapy to a tumor, the second control means further for applying, based on the control command, the electric power to the light emitting diode to emit a predetermined wavelength of light to the photosensitizer to provide photodynamic therapy to the tumor.

A flexible catheter is inserted into the esophagus to cool or warm the esophagus, particularly during certain procedures which can tend to change the temperature in the area of the esophagus. The catheter is inserted through the mouth and throat to a position, for example, proximate the heart, but within the esophagus. One or more balloons are inflated to block areas of the esophagus, while a gel is injected into the esophagus where it is immobilized by the one or more balloons. A coolant is pumped through a coolant tube affixed to the catheter, where it exchanges heat with the conductive gel.

Provided are devices and methods for anesthetizing a patient undergoing surgery, and/or pain block procedures. In certain embodiments the disclosure provides a curved cryoneurolysis needle. In some forms, the methods include inserting at least one cryoneurolysis needle into a target region of the patient, and cooling the cryo-needle to inhibit the target intercostal nerve.

An apparatus and method use a catheter for specific and discriminate treatment of central nervous system disease. With the catheter, selective hypothermia to the brain and/or the spinal cord for injury protection can be achieved without the need for systemic cooling. The catheter is also capable of draining excess cerebrospinal fluid.

The present invention provides a method and device for non-invasive anatomical and systemic cooling, fluid removal and/or energy removal. The method and device provide for removal of fluid and cooling of various bodily fluid-containing spaces or surfaces, such as mucus-containing spaces or surfaces via delivery of a dry fluid not including a coolant into or upon the mucus-containing space or surface. Exposure of such mucus to the dry fluid results in evaporation of body fluid, removal of energy, cooling of the anatomical feature, and systemic cooling. In this fashion, therapeutic hypothermia may be achieved to provide for neuroprotection of various organs after ischemic insult, such the brain after cardiac arrest. Similarly, excess fluid removal may be achieved for treatment of cardiogenic shock or other conditions that cause significant fluid build-up, especially in cases of compromised renal function. Additionally, the invention may be used to reduce fever, and other conditions where removal of heat, energy and/or water are beneficial.

We report a method of treating an epileptic seizure in a patient, comprising: detecting said epileptic seizure, based on body data from said patient; and reducing a flow of blood to a brain of said patient in response to said detected seizure; wherein said reducing is effected by: increasing the parasympathetic input to said patient's heart, such as by electrically stimulating a parasympathetic nervous structure, applying cooling energy to a sympathetic nervous structure, or administering a cholinergic or a sympatho-blocking agent to said patient. We also report a medical device system configured to implement the method. We also report a non-transitory computer readable program storage unit encoded with instructions that, when executed by a computer, perform the method.