Gaseous nanobubbles are created and infused into the blood stream to therapeutic effect such as oxygenation. The nanobubbles may be created inside or outside of the patient, either during infusion or prior to infusion. CO2 is extracted from the blood to improve oxygen.

Gaseous nanobubbles are created and infused into the blood stream to therapeutic effect such as oxygenation. The nanobubbles may be created inside or outside of the patient, either during infusion or prior to infusion. CO2 is extracted from the blood to improve oxygen.

Initial liquid containing fine bubbles is produced by mixing water and air (step S11). Fine bubbles have diameters of less than 1 m. The density of bubbles in the initial liquid is measured (step S13), and when the measured density is less than a target density (step S14), the initial liquid is heated and reduced in pressure so that the liquid is vaporized (step S15). As a volume of the liquid decreases, the density of fine bubbles increases, and high-density fine bubble-containing liquid is easily obtained. Alternatively, by increasing the density of fine bubbles in the initial liquid with using a filter that does not pass all fine bubbles, high-density fine bubble-containing liquid is easily acquired (step S15). When the density of bubbles in the initial liquid is greater than the target density, the initial liquid is diluted (step S16).

A water purification system according to various embodiments of the present technology is configured to regulate the flow rate of the water and infuse the water with oxygen. The water purification system may comprise various valves, fittings, couplings, pumps, and filters configured to remove debris from the water and regulate the flow of the water through various filters. The water purification system may comprise a controller to electrically control various valves and pumps. The water purification system may comprise a device for infusing the water with oxygen.

Provided is a pharmaceutical composition excellent in capability of an accelerated penetration into an affected area. The pharmaceutical composition capable of accelerated penetration into the affected area is formed by dispersing nano-bubbles, which are negatively charged and are given high internal pressures due to their surface tension, in the pharmaceutical composition in a form of a liquid or a gel including a predetermined drug.

The invention discloses a novel micro bubble generating mechanism, and relates to the technical field of wine treatment, the novel micro bubble generating mechanism comprises a micro bubble generator body, a water molecule bubble generator, a high-speed rotating blade, an air pressure conversion mechanism and a high-grade stainless steel high-density gauze, one end of the micro bubble generator body is provided with an inlet, and from one end to the other end of the micro bubble generator body itself there is provided with in sequence the water molecule bubble generator, the air pressure conversion mechanism and the high-grade stainless steel high-density gauze. Through the arrangement of the micro bubble generating mechanism, a traditional decanting mode is broken.

The invention discloses a novel micro bubble generating mechanism, and relates to the technical field of wine treatment, the novel micro bubble generating mechanism comprises a micro bubble generator body, a water molecule bubble generator, a high-speed rotating blade, an air pressure conversion mechanism and a high-grade stainless steel high-density gauze, one end of the micro bubble generator body is provided with an inlet, and from one end to the other end of the micro bubble generator body itself there is provided with in sequence the water molecule bubble generator, the air pressure conversion mechanism and the high-grade stainless steel high-density gauze. Through the arrangement of the micro bubble generating mechanism, a traditional decanting mode is broken.

Provided are a method and apparatus for generating ultrafine bubbles in a liquid. The method involves introducing, in real time, and at a time when dispensation of the liquid with ultrafine bubbles is to occur, the liquid into a liquid chamber. A bubble generator is activated to impart a shearing force on the liquid within the liquid chamber to cause cavitation of the liquid that results in formation of the ultrafine bubbles. The liquid containing the ultrafine bubbles that exits the liquid chamber is dispensed, to be imparted onto a target object.

Provided are a method and apparatus for generating ultrafine bubbles in a liquid. The method involves introducing, in real time, and at a time when dispensation of the liquid with ultrafine bubbles is to occur, the liquid into a liquid chamber. A bubble generator is activated to impart a shearing force on the liquid within the liquid chamber to cause cavitation of the liquid that results in formation of the ultrafine bubbles. The liquid containing the ultrafine bubbles that exits the liquid chamber is dispensed, to be imparted onto a target object.

Embodiments include a system for generating nanobubbles in a solvent, including a device for generating a reverse and forward flow in the solvent, wherein the solvent has one or more gases dissolved in it; and a Tesla valve fluidly coupled to the device, wherein the device pushes the solvent through the Tesla valve one or more times alternatingly in a forward and reverse direction to generate nanobubbles of a desired concentration and size. Aspects include a method for generating nanobubbles in a solvent, including filling a device with a desired solvent containing one or more gases dissolved in it; wherein the device is capable of generating a reverse and forward flow in the solvent, and wherein a Tesla valve is fluidly coupled to the device; and using the device to push the solvent through the Tesla valve one or more times alternatingly in forward and reverse directions to generate nanobubbles.