JP2014512207A5 - - Google Patents

Claims (35)

A control system for a handheld vapor delivery device comprising:
To provide a consistent and reliable dosage , providing a sufficient amount of power from the power source to heat the heating element to the minimum required temperature to fully vaporize a given volume of liquid A control system comprising a circuit configured to control a deficiency duration so as to supply the deficient amount of power to completely vaporize the predetermined volume of the liquid at the required temperature .   The control system of claim 1, wherein the circuit comprises a one-shot circuit.   The processing apparatus further comprises a processor programmed to monitor the resistance of the heating element and adjust the amount of power to a level sufficient to heat the heating element to the required temperature. The control system described in.   The circuit comprises a DC / DC boost converter and a supercapacitor operably connected to the power supply to adjust the amount of power to the level sufficient to heat the heating element to the required temperature. The control system according to claim 1.   The control system of claim 1, wherein the circuit is configured to activate the power source a predetermined number of times. a. A housing having a first end and a second end;
b. A mouthpiece attached to the first end;
c. A fluid delivery system;
d. A vaporization system comprising a heating element between the mouthpiece and the fluid delivery system ;
e. Provide a sufficient amount of power from a power source to heat the heating element to a temperature required to completely vaporize the liquid excess and deficiency volume, and the liquid deficiency at the required temperature. A power control system comprising a circuit configured to control a deficiency duration so as to provide the deficient amount of power for complete vaporization of an empty volume; and a handheld drug delivery comprising: device.   The handheld drug delivery device of claim 6, wherein the control system comprises a one-shot circuit.   The hand-held drug of claim 6, wherein the circuit comprises a processing device programmed to monitor the resistance of the heating element and adjust the power until the heating element reaches the required temperature. Delivery device.   The handheld drug delivery device of claim 6, wherein the control system comprises a DC / DC boost converter operably connected to a supercapacitor.   The hand-held drug delivery device of claim 6, wherein the circuit comprises a processing device programmed to activate the power source a predetermined number of times.   The handheld drug delivery device of claim 6, wherein the power source is an alkaline battery. The fluid delivery system comprises:
a. A fluid reservoir located inside the housing and having a first end and a second end;
b. A volume that is positioned at the second end inside the fluid reservoir and is gradually advanced toward the first end at a fixed and discrete distance, so that there is no excess or deficiency of liquid from the fluid reservoir. 7. A handheld drug delivery device according to claim 6, comprising a pressure generator configured to consistently measure the pressure.   The fluid delivery system further comprises a cap in fluid communication with the fluid reservoir at the first end, the cap having an outlet on the opposite side of the fluid reservoir, the positive end being in the fluid reservoir. 13. The handheld drug delivery of claim 12, wherein when the pressure is applied, the liquid stored inside the fluid reservoir can exit the outlet and form a droplet at the outlet. device.   14. Handheld drug delivery according to claim 13, wherein the outlet and the heating element are separated by a smaller distance than the droplet so that the droplet can contact the heating element while located on the outlet. device. The pressure generator is
a. A piston housed inside the fluid reservoir and configured to push the liquid through the cap;
b. A fluid discharge actuation device operably connected to the piston, and actuating the fluid discharge actuation device to advance the piston toward the first end at the fixed and discrete distance; The handheld drug delivery device according to claim 13.   13. The permeable membrane of claim 12, further comprising a permeable membrane positioned between the mouthpiece and the heating element, wherein the permeable membrane is permeable to vapor molecules of a predetermined size. Handheld drug delivery device. a. A housing having a first end and a second end;
b. A mouthpiece attached to the first end;
c. A fluid delivery system comprising:
i. A fluid reservoir located inside the housing and having a first end and a second end; and ii. A volume that is positioned at the second end inside the fluid reservoir and is gradually advanced toward the first end at a fixed and discrete distance, so that there is no excess or deficiency of liquid from the fluid reservoir. Fluid delivery system comprising a pressure generator configured to consistently measure
d. A vaporization system comprising a heating element between the mouthpiece and the fluid reservoir;
e. And a control system for delivering power to the vaporization system.   The fluid delivery system further comprises a cap in fluid communication with the fluid reservoir at the first end, the cap having an outlet on the opposite side of the fluid reservoir, the positive end being in the fluid reservoir. 18. The hand-held drug delivery of claim 17, wherein when the pressure is applied, the liquid stored inside the fluid reservoir can exit the outlet and form a droplet at the outlet. device.   19. The handheld of claim 18, wherein the outlet and the heating element are separated by a distance less than the droplet so that the droplet can contact the heating element while located on the outlet at the opening. Drug delivery device. The pressure generator is
a. A piston housed inside the fluid reservoir and configured to push the liquid through the cap;
b. A fluid discharge actuation device operably connected to the piston, and actuating the fluid discharge actuation device to advance the piston toward the first end at the fixed and discrete distance; 19. A handheld drug delivery device according to claim 18.   18. The permeable membrane of claim 17, further comprising a permeable membrane positioned between the mouthpiece and the heating element, wherein the permeable membrane is permeable to vapor molecules of a predetermined size. Handheld drug delivery device. A method for efficiently and consistently evaporating an excess or deficiency of liquid medication from a handheld device,
a. Consistently measuring the volume of liquid in the heating element without excess or deficiency;
b. Supplying from a power source a power amount that is sufficient to heat the heating element over a time period that is free of excess or deficiency, wherein the combination of the power amount without excess and deficiency and the duration time without excess or deficiency, Heating the heating element to a minimum required temperature for a minimum time required to completely vaporize the excess-deficient volume of the liquid. Measuring the volume of the liquid without excess or deficiency;
a. Storing the liquid in a fluid reservoir;
b. 23. The method of claim 22, comprising applying a positive pressure deficiency amount inside the fluid reservoir to drain a deficient volume of fluid from the fluid reservoir. 24. The method of claim 23, wherein a non-abundant amount of the positive pressure is applied by gradually advancing a plunger a predetermined distance within the fluid reservoir.   25. The method of claim 24, wherein advancing the plunger by the predetermined distance is accomplished by turning a drive nut to provide a fixed rotational motion.   26. The method of claim 25, wherein turning the drive nut is accomplished by actuating a button, and the button turns the drive nut to cause the fixed rotational motion each time it is actuated.   23. The method according to claim 22, wherein supplying the amount of power without excess or deficiency is realized by programming a processing device to operate the power supply a predetermined number of times. Supplying the electric energy without excess or deficiency,
a. Monitoring the temperature of the heating element while supplying the power;
b. Comparing the temperature of the heating element to a predetermined temperature;
c. 23. The method of claim 22, comprising adjusting the deficiency duration for which the deficient amount of power is supplied based on the comparison. Supplying the electric energy without excess or deficiency,
a. Monitoring the temperature of the heating element while supplying the power;
b. Comparing the temperature of the heating element to a predetermined temperature;
c. 23. The method of claim 22, comprising adjusting the amount of power supplied based on the comparison.   30. The method of claim 29, wherein monitoring the temperature of the heating element is realized by measuring a resistance in the heating element.   30. The method of claim 29, further comprising a supercapacitor operably connected to the power source and the processing device to regulate the amount of power supplied.   32. The method of claim 31, wherein the power source is an alkaline battery.   23. The method of claim 22, wherein the step of supplying power is initiated by creating an air flow in a mouthpiece of the handheld device.   The method further comprises controlling the size of the vapor molecules of the vaporized liquid by disposing a permeable membrane between the heating element and the mouthpiece, the permeable membrane having a predetermined size. 34. A method according to claim 33, which is permeable only to vapor molecules. A control system for a handheld vapor delivery device comprising:
a. Means for providing a sufficient amount of power from a power source to heat the heating element to a minimum required temperature to fully vaporize a given volume of liquid;
b. A control system comprising: means for controlling a deficiency duration so as to supply the deficient amount of power for completely vaporizing the predetermined volume of the liquid at the required temperature.