A medicine vaporizer apparatus comprises a base with an upwardly extending heating element disposed within a rigid tube. Air is drawn into the rigid tube through an aperture in the rigid tube below the heating element and directed over the heating element to then be drawn through a flexible tube and through a filter or screen comprising an amount of medicine. Heated air flows over the amount of medicine and vaporizes the same, wherein the medicine is thereafter drawn into the lungs of a patient pulling the air therethrough with his or her mouth. Thermal separation and cooling of various parts prevents accidental injury to users and provides an inert air path for the air therethrough. The apparatus further provides controlled incineration and/or vaporization of the medicine.

The present invention relates to an insufflator for laparoscopy, comprising a suction pump, the suction pump being connected to the patient through a separate hose and permitting a controlled ventilation.

The present invention relates to an insufflator for laparoscopy, comprising a suction pump, the suction pump being connected to the patient through a separate hose and permitting a controlled ventilation.

A hydrogen-delivering system for topical application of molecular hydrogen is provided. The system includes a housing that comprises at least one dry chemical and a liquid composition sealed therein, and that is configured to be attached to a target area of a subject's skin. The dry chemical and the aqueous composition are separated within the housing until the system is activated and the dry chemical and the aqueous composition are mixed to generate molecular hydrogen. The molecular hydrogen passes through a skin-facing surface of the housing, which is permeable to hydrogen and not permeable to the dry chemical and the aqueous composition, and is delivered to the subject's body.

A gas mixture apparatus includes a measurement control system, an activation system, a pressurized chamber with one or more gases, and a mixing chamber. The apparatus can also include additional pressure regulation control systems. The gas mixture apparatus can be used to introduce and automatically perform the steps to achieve a desired concentration of the one or more gases contained in the pressurized chamber. The gas mixture apparatus can include the pressurized chamber within the apparatus itself such that no external devices are necessary for introducing the one or more gases into the mixing chamber.

Systems and methods according to present principles meet the needs of the above in several ways, and in particular provide a product that can continuously monitor and remove air from the stomach without removing liquid from a premature neonate's stomach. The device works by providing suction pressure of, e.g., 100.1 mmHg through the feeding tube to continuously remove air from the stomach. In this way the device prevents the problem of gastric distension all together. The pressure may be regulated by using an electronic control valve.

A hemodialysis system configured to purge air from a blood circuit comprises a dialyzer; a dialysis fluid circuit operable with the dialyzer via dialysis fluid inlet and outlet lines, the dialysis fluid circuit including a fresh dialysis fluid pump, and a used dialysis fluid pump; the blood circuit operable with the dialyzer and including an arterial line, a venous line, a blood pump operable with the arterial line upstream of the dialyzer, a physiologically acceptable fluid source in fluid communication with the arterial line upstream of the blood pump, a drip chamber located along the venous line, and a container for accepting air purged from the blood circuit; and an air purging scheme wherein, with the dialysis fluid inlet and outlet lines connected to the dialyzer, the blood pump pumps a fluid through the dialyzer and into the drip chamber, forcing air from the drip chamber into the container.

A gas mixing system for providing mixed gas for intraocular injection. In some embodiments, a first fixed-volume chamber is automatically purged and filled with gas from a first gas supply input, to a first predetermined pressure. A second fixed-volume chamber is purged and filled with gas from a second gas supply input, to a second predetermined pressure. The first and second predetermined pressures are determined based on a desired concentration of gases in the final mix, and the respective volumes of the first and second fixed-volume chambers and of a third fixed-volume chamber. Gas from the first fixed-volume chamber is then allowed to mix with gas in the third fixed-volume chamber, which was previously purged. Next, gas from the second fixed-volume chamber is allowed to mix with gas in the third fixed-volume chamber. Finally, the mixture of gases in the third fixed-volume chamber is expressed into an intraocular syringe.

A vented chest wound seal for a penetrating chest wound including a flexible sheet including a bottom surface, and an adhesive layer covering a portion of the bottom surface of the flexible sheet, the adhesive layer including an inner perimeter and an outer perimeter, the inner perimeter defining a chamber, wherein the chamber includes a vent channel extending radially outward from a central portion of the chamber, wherein the flexible sheet includes a vent hole aligned over the vent channel, and wherein the inner perimeter and the outer perimeter are separated by a minimum hydrogel width.

The present invention provides a gas generator and comprises an electrolytic cell, a gas pathway, and an anti-static device. The electrolytic cell is for electrolyzing electrolyzed water to generate a gas with hydrogen. The gas generated from the electrolytic cell is transferred by the gas pathway. The anti-static device is set in the gas generator for reducing or eliminating the static electricity. The present invention uses the anti-static device to prevent the gas with hydrogen in the gas pathway from exploding by the static electricity, thereby providing a safe gas generator.