Abstract: A ventilator adaptor for switching between ventilator devices while maintaining respiratory support to a patient is described. The ventilator adaptor has a first movable element with a first inlet and a second inlet, and a second movable element movably attached to the first movable element and with an outlet. The outlet has an inner diameter of 14.5-15.5 mm, preferably 15 mm, and the first inlet and the second inlet have an outer diameter of 14.5-15.5 mm, preferably 15 mm. The outlet is in fluid communication with the first inlet in a first position or with the second inlet in a second position by moving the second movable element relative to the first movable element thereby aligning the outlet with the first inlet or the second inlet. The outlet may be attached to an endotracheal tube in order to form a ventilation assembly.

Abstract: A ventilator adaptor for switching between ventilator devices while maintaining respiratory support to a patient is described. The ventilator adaptor has a first movable element with a first inlet and a second inlet, and a second movable element movably attached to the first movable element and with an outlet. The outlet has an inner diameter of 14.5-15.5 mm, preferably 15 mm, and the first inlet and the second inlet have an outer diameter of 14.5-15.5 mm, preferably 15 mm. The outlet is in fluid communication with the first inlet in a first position or with the second inlet in a second position by moving the second movable element relative to the first movable element thereby aligning the outlet with the first inlet or the second inlet. The outlet may be attached to an endotracheal tube in order to form a ventilation assembly.

Abstract: A ventilator adaptor for switching between ventilator devices while maintaining respiratory support to a patient is described. The ventilator adaptor has a first movable element with a first inlet and a second inlet, and a second movable element movably attached to the first movable element and with an outlet. The outlet has an inner diameter of 14.5-15.5 mm, preferably 15 mm, and the first inlet and the second inlet have an outer diameter of 14.5-15.5 mm, preferably 15 mm. The outlet is in fluid communication with the first inlet in a first position or with the second inlet in a second position by moving the second movable element relative to the first movable element thereby aligning the outlet with the first inlet or the second inlet. The outlet may be attached to an endotracheal tube in order to form a ventilation assembly.

Abstract: The present disclosure relates to a surgical tool for cutting and hemostasis of biological tissues. The surgical tool includes a hollow blade comprising a cutting implement residing within a hollow cavity configured to provide high-pressure steam through an apical surface. The cutting implement can operate independently or in cooperation with the provided high-pressure steam. The surgical tool of the present disclosure applies a directionally-controlled, high-pressure steam flow to a tissue region of interest. A control unit provides temperature-controlled steam at a flow-rate determined in accordance with tissue type and intended procedure.

Abstract: A medical device containing a sensor, a motor, one or more plates, and a control unit, for treating diabetes. The medical device vibrates the pancreas thereby improving blood and secretory hormone circulation and enhancing the production of insulin.

Abstract: A ventilator adaptor for switching between ventilator devices while maintaining respiratory support to a patient is described. The ventilator adaptor has a first movable element with a first inlet and a second inlet, and a second movable element movably attached to the first movable element and with an outlet. The outlet has an inner diameter of 14.5-15.5 mm, preferably 15 mm, and the first inlet and the second inlet have an outer diameter of 14.5-15.5 mm, preferably 15 mm. The outlet is in fluid communication with the first inlet in a first position or with the second inlet in a second position by moving the second movable element relative to the first movable element thereby aligning the outlet with the first inlet or the second inlet. The outlet may be attached to an endotracheal tube in order to form a ventilation assembly.

Abstract: The present disclosure relates to a surgical tool for cutting and hemostasis of biological tissues. The surgical tool includes a hollow blade comprising a cutting implement residing within a hollow cavity configured to provide high-pressure steam through an apical surface. The cutting implement can operate independently or in cooperation with the provided high-pressure steam. The surgical tool of the present disclosure applies a directionally-controlled, high-pressure steam flow to a tissue region of interest. A control unit provides temperature-controlled steam at a flow-rate determined in accordance with tissue type and intended procedure.

Abstract: A ventilator adaptor for switching between ventilator devices while maintaining respiratory support to a patient is described. The ventilator adaptor has a first movable element with a first inlet and a second inlet, and a second movable element movably attached to the first movable element and with an outlet. The outlet has an inner diameter of 14.5-15.5 mm, preferably 15 mm, and the first inlet and the second inlet have an outer diameter of 14.5-15.5 mm, preferably 15 mm. The outlet is in fluid communication with the first inlet in a first position or with the second inlet in a second position by moving the second movable element relative to the first movable element thereby aligning the outlet with the first inlet or the second inlet. The outlet may be attached to an endotracheal tube in order to form a ventilation assembly.

Abstract: A nebulizer tubing including an inlet configured to be connected to a gas source and an outlet configured to be connected to a nebulizer. The nebulizer tubing includes a port configured to be covered during inhalation to allow airflow from the gas source to the nebulizer and uncovered during exhalation to stop the airflow from the gas source to the nebulizer by allowing gas to escape from the nebulizer tubing. The airflow activates a nebulization process.

Abstract: The present disclosure relates to a surgical tool for cutting and hemostasis of biological tissues. The surgical tool includes a hollow blade comprising a cutting implement residing within a hollow cavity configured to provide high-pressure steam through an apical surface. The cutting implement can operate independently or in cooperation with the provided high-pressure steam. The surgical tool of the present disclosure applies a directionally-controlled, high-pressure steam flow to a tissue region of interest. A control unit provides temperature-controlled steam at a flow-rate determined in accordance with tissue type and intended procedure.

Abstract: The present disclosure relates to a surgical tool for cutting and hemostasis of biological tissues. The surgical tool includes a hollow blade comprising a cutting implement residing within a hollow cavity configured to provide high-pressure steam through an apical surface. The cutting implement can operate independently or in cooperation with the provided high-pressure steam. The surgical tool of the present disclosure applies a directionally-controlled, high-pressure steam flow to a tissue region of interest. A control unit provides temperature-controlled steam at a flow-rate determined in accordance with tissue type and intended procedure.

Abstract: A medical device containing a sensor, a motor, one or more plates, and a control unit, for treating diabetes. The medical device vibrates the pancreas thereby improving blood and secretory hormone circulation and enhancing the production of insulin.

Abstract: A ventilator adaptor for switching between ventilator devices while maintaining respiratory support to a patient is described. The ventilator adaptor has a first movable element with a first inlet and a second inlet, and a second movable element movably attached to the first movable element and with an outlet. The outlet has an inner diameter of 14.5-15.5 mm, preferably 15 mm, and the first inlet and the second inlet have an outer diameter of 14.5-15.5 mm, preferably 15 mm. The outlet is in fluid communication with the first inlet in a first position or with the second inlet in a second position by moving the second movable element relative to the first movable element thereby aligning the outlet with the first inlet or the second inlet. The outlet may be attached to an endotracheal tube in order to form a ventilation assembly.

Abstract: A system and method is provided for conditioning a group of muscles and joints of a subject including: a movement assembly including an arm having a handle, such that an angular position is created by the subject's joint when the subject grips the handle, a brake, connected to the movement assembly, configured to apply a work load to the movement assembly, and a sensor configured to sense the angular position of the movement assembly; and a computing device, in communication with the sensor and the brake, configured to sense the movement of the movement assembly relative to the brake, create an encoded signal representing the movement assembly and the movement over a period of time, and modify the brake to vary the work load during a movement of the movement assembly based on timing at the angular position and a predetermined regimen.

Abstract: A nebulizer tubing comprising an inlet configured to be connected to a gas source and an outlet configured to be connected to a nebulizer. The nebulizer tubing comprises a port configured to be covered during inhalation to allow airflow from the gas source to the nebulizer and uncovered during exhalation to stop the airflow from the gas source to the nebulizer by allowing gas to escape from the nebulizer tubing. The airflow activates a nebulization process.

Abstract: A diaphragm respiratory signal simulator is activated by skin voltage that is coupled to the simulator by many ways such as but not limited to a user sliding a finger over a conductive surface, the user sliding a finger over surfaces close to the conductive element, touch or sliding the finger over the ventilator screen. The conductive surface is electrically connected to a ring electrode at a distal part of a manikin's esophagus. The diaphragm respiratory signal simulator produces a synthetic diaphragm electrical signal that triggers a ventilator to deliver a supported breath, which is proportional to the strength of the generated signal. This process allows safe and successful training on the operations of NAVA mode of ventilation and catheter positioning.

Abstract: A diaphragm respiratory signal simulator is activated by skin voltage that is coupled to the simulator by many ways such as but not limited to a user sliding a finger over a conductive surface, the user sliding a finger over surfaces close to the conductive element, touch or sliding the finger over the ventilator screen. The conductive surface is electrically connected to a ring electrode at a distal part of a manikin's esophagus. The diaphragm respiratory signal simulator produces a synthetic diaphragm electrical signal that triggers a ventilator to deliver a supported breath, which is proportional to the strength of the generated signal. This process allows safe and successful training on the operations of NAVA mode of ventilation and catheter positioning.