Claims
- 1. A method of manipulating a solid, which comprises:
(a) providing a bed of powder of known weight and uniform height; (b) inserting a tube a controlled distance into the bed to obtain a plug of powder, wherein the tube has an interior that accommodates a means of ejecting materials from within the tube; (c) removing the tube from the bed; and (d) ejecting the plug of powder.
- 2. The method of claim 1, wherein:
(a) the tube is inserted completely through the bed; (b) the plug of powder is obtained by compression; (c) the means of ejecting the plug is a piston, vibration, pressurized gas, or a liquid; (d) the means of ejecting the plug of (c) is a piston; (e) the method does not substantially affect the form of the solid; or (f) the powder comprises an active pharmaceutical ingredient.
- 3. A method for dispensing a controlled mass of a solid, which comprises:
(a) processing the solid into a powder with an average particle size of less than about 200 micrometers; (b) forming a powder bed with a predetermined mass and uniform height from a portion of the powder; (c) inserting a tube a controlled distance into the powder bed to obtain a plug of powder, wherein the tube has an interior that accommodates a means for ejecting materials from within the tube; (d) lifting the tube from the powder bed; (e) moving the tube over a target location; and (f) ejecting a plug of powder onto target location.
- 4. The method of claim 3, wherein:
(a) the method further comprises:
(i) providing a grille plate with an array of holes sized so that the tube can pass through each with a small clearance; and (ii) holding the grille plate on top of the powder bed; the powder bed is prevented from breaking apart upon insertion of the tube; (c) a method to form the powder bed comprises:
(i) providing a source receptacle assembly comprising:
(1) a source receptacle with sides, a top surface, a bottom face, and at least one cylindrical hole that passes through and is perpendicular to the bottom face; and (2) a base plate that is removeably attached to the bottom face;
(ii) dispensing a predetermined mass of the powder into the cylindrical hole; (iii) providing a cylindrical pin with at least one flat, perpendicular end face; (iv) inserting the cylindrical pin into the cylindrical hole and pressing the pin into the powder with a predetermined force; (v) rotating the cylindrical pin through an angle of at least 1 degree of rotation with the predetermined force applied; and simultaneously rotating and lifting the pin out of the cylindrical hole; (d) a method is used for forming the powder bed comprising the steps of:
(i) providing a source receptacle assembly comprising:
(1) a source receptacle with sides, a top face, a bottom surface, and at least one cylindrical hole that passes through and is perpendicular to the top face; (2) a close fitting cylinder disposed inside of the cylindrical hole; and (3) a cylinder locking means which allows the close fitting cylinder to be either locked to or disengaged from the source receptacle; (ii) dispensing a predetermined mass of the powder into the cylindrical hole through the top face of the source receptacle; (iii) providing a slide plate with at least one flat face; (iv) pressing the flat face of the slide plate against the top face of the source receptacle; (v) disengaging the cylinder locking means; (vi) pressing the cylinder into the powder with a predetermined force; (vii) rotating the cylinder through an angle of at least 1 degree of rotation with the predetermined force applied; (viii) engaging the cylinder locking means; and sliding the slide plate off of the top face of the source receptacle; (e) pressures applied to the powder are low enough so as to not substantially affect the form of the powder; (f) the powder comprises an active pharmaceutical ingredient; (g) the ejecting means is a close fitting pin disposed in the interior of the tube; (h) the plug inside the tube is compressed prior to being ejected; (i) the tube is inserted completely through the powder bed; (j) the ejecting means is a close fitting pin with sides and a face disposed in the interior of the tube, and the close fitting pin is held stationary relative to the tube while the tube is inserted into the powder bed a predetermined depth sufficient to make the pin face contact the powder; (k) the tube is inserted into the powder with a predetermined force applied to it; (l) the tube is inserted into the powder bed a predetermined depth; (m) the tube is a hollow needle; or (n) a wide variety of solids can be dispensed in controlled amounts without substantially affecting their form.
- 5. An apparatus for manipulating a solid, which comprises:
(a) a punching assembly comprising a tube having an interior, a piston located within the interior of the tube, a first actuator capable of adjusting the vertical position of the tube, and a second actuator capable of moving the piston within the tube; (b) a powder bed assembly mounted below the punching assembly, comprising a source plate and a receiving plate; and (c) a means of positioning the punching assembly over the source plate and the receiving plate.
- 6. An apparatus for dispensing powder which comprises:
(a) a punching assembly comprising a tube having an interior, close fitting pin disposed inside the interior of the tube, a first actuator capable of adjusting the vertical position of the tube, a second actuator capable of moving the pin within the tube; (b) a source station comprising at least one powder bed of predetermined mass and uniform height, and a structure to support the powder bed; (c) a receiving plate mounted below the punching assembly; and (d) a means for positioning the punching assembly over the source plate and the receiving plate.
- 7. The apparatus of claim 6, wherein:
(a) the first actuator and the second actuator are pneumatically driven linear actuators; (b) the first actuator and the second actuator are electronically driven linear servos; (c) the means for positioning the punching assembly comprises perpendicularly mounted electronically driven linear servos; (d) a wash station is included which contains means for washing away powder from the tube and the pin, and drying the hollow needle and the pin; (e) a weigh station is included which contains means for weighing powder that is dispensed into it; (f) the tube is a hollow needle; or (g) a wide variety of solids can be dispensed in controlled amounts without substantially affecting their form.
- 8. A method of manipulating a solid, which comprises:
(a) blending a controlled amount of the solid with a liquid to provide a slurry; (b) dispensing a controlled amount of the slurry; and (c) removing the liquid to provide an amount of the solid, wherein the amount of the solid is less than about 1 mg.
- 9. The method of claim 8, wherein:
(a) the amount of solid is less than about 0.5 mg; (b) the amount of solid is less that about 100 micrograms; (c) the means of removing the liquid is evaporation, filtration, or sedimentation; (d) the solid comprises an active pharmaceutical ingredient; (d) the solid comprises an active pharmaceutical ingredient; (e) the method does not substantially affect the form of the solid; (f) the liquid comprises a wetting agent and water; (g) the wetting agent is isopropyl alcohol, methanol, PVP, Tween®, or sodium lauryl sulfate; or (h) solid state analysis is performed after removing the liquid to verify that the solid has not changed form.
- 10. A method of manipulating a solid, which comprises:
contacting particles of the solid with a surface comprising a plurality of discrete adhesive areas separated by non-adhesive areas, wherein the size of the adhesive areas is smaller than about 5 cm2, under conditions sufficient to adhere the particles non-electrostatically to an adhesive area; and adhering the particles non-electrostatically to the adhesive area.
- 11. The method of claim 10, wherein:
less than about 1 mg of solid is adhered to an adhesive area; less than about 0.5 mg of solid is adhered to an adhesive area; (c) less than about 0.25 mg of solid is adhered to an adhesive area; (d) the adhesive material is a pressure sensitive adhesive, a silicone, or a hydrogel; (e) the solid comprises an active pharmaceutical ingredient; or (f) the method does not substantially affect the form of the solid.
- 12. An apparatus for manipulating a solid, which comprises:
(a) a surface, comprising a plurality of discrete adhesive areas separated by non-adhesive areas, wherein the size of the adhesive areas is smaller than about 5 cm2, under conditions sufficient to adhere the particles non-electrostatically to an adhesive area at least a portion of which is coated with an adhesive; (b) a container capable of holding powder; and (c) a means of contacting the adhesive portion of the surface with powder in the container.
- 13. The apparatus of claim 12, wherein the adhesive material is a pressure sensitive adhesive, a silicone, or a hydrogel.
- 14. A method for manipulating a solid, which comprises:
dispensing a known amount of solid into a source chamber; compressing the solid; moving a slide plate such that a dose chamber traverses the solid; moving the dose chamber over a target well; and ejecting a plug of solid.
- 15. The method for manipulating a solid of claim 14, wherein
(a) the slide plate in step (c) is moved in a criss-cross or in a spiral trajectory; or (b) the source chamber is subjected to vibration or mixing in step (c).
- 16. An apparatus for manipulating a solid, which comprises:
a slide plate comprising a dose chamber; a powder bed assembly mounted below the slide plate, comprising a source chamber and a receiving plate; and a means for positioning the slide plate over the source plate and the receiving plate.
- 17. The apparatus for manipulating a solid of claim 16, wherein:
the apparatus further comprises a microbalance; or the slide plate comprises a dose chamber in the form of a grid cutter.
- 18. A method of manipulating a solid, which comprises:
dispensing a known amount of solid into a source chamber; compressing the solid; moving a slide plate directly below the source chamber; pressing the solid through a grid cutter to make multiple plugs; moving the slide plate to an ejector pin; and propelling ejector pin down to eject a solid plug into a target well.
- 19. The method of claim 18, wherein:
the height of each partition in the grid cutter is controlled by a micrometer; the target well is controlled by an x servo and a y servo; or the target well is controlled by an x linear actuator and a y linear actuator.
- 20. A method of transferring a solid, which comprises:
gripping a vessel containing a solid with a clamp; attaching a swing arm to the clamp; accelerating the swing arm through an arc trajectory until a hard stop is impacted; and placing a target well directly below the stopped position of the vessel.
- 21. The method of claim 20, wherein:
a carousel enables simultaneous transferring and weighing; the target well is controlled by an x servo and a y servo; the target well is controlled by an x linear actuator and a y linear actuator; solid transfer is promoted by a vibrating actuator; or premature solid transfer is prevented by a retractable shield.
- 22. An apparatus for transferring a solid, which comprises:
a vessel containing a solid gripped by a clamp; a swing arm attached to the clamp; a hard stop; a target well; and an x actuator and a y actuator to control the position of the target well.
- 23. The apparatus of claim 22, wherein:
the actuators are linear servos; the apparatus further comprises a carousel; the apparatus further comprises a vibrating actuator; the apparatus further comprises a retractable shield; the target vessel is a multi-well plate; or the apparatus further comprises a microbalance.
- 24. A method of transferring a solid, which comprises:
gripping a vessel with a mechanical device mounted to xy linear actuators; and moving the vessel between a receiving plate and a microbalance using the mechanical device mounted to the xy linear actuators.
- 25. An apparatus for transferring a solid, which comprises:
a vessel gripped by a mechanical device; the mechanical device is mounted to xy linear actuators; a receiving plate; and a microbalance.
- 26. A method for mixing small amounts of solids, which comprises:
placing the solid in a filter-bottom well; sealing the well; and injecting gas into the well.
- 27. The method of claim 26, wherein:
the well is sealed with a filter plate; the well is sealed with a lid; or the seal is pierceable.
- 28. An apparatus for mixing small amounts of solids, which comprises:
a well with a filter bottom containing solids; a seal; and a means for injecting gas into the well.
- 29. A method to weigh a small amount of solid, which comprises:
supporting a low-mass container with a cradle; positioning the cradle so the low-mass container is above a weigh platform; lowering the cradle so the low-mass container is supported by the weigh platform; and weighing the solid.
- 30. An apparatus to weigh a small amount of solid, which comprises:
a low mass container containing solid and supported by a cradle; a weigh platform; and means for lowering the cradle so the low-mass container is supported by the weigh platform.
- 31. The apparatus of claim 30, further comprising:
xy linear actuators; or a two-dimensional array of low-mass containers.
- 32. A method for measuring the mass of a small amount of solid, which comprises:
coring a plug of powder with a coring tube; generating a voltage signal; applying the voltage signal to a piezoelectric actuator affixed to the coring tube; and measuring the displacement of the coring tube with a laser.
- 33. The method of claim 32, wherein:
the voltage signal is a swept-sine signal; or the frequency of the applied voltage signal is between 6.3 kHz and 7.1 kHz.
- 34. An apparatus for measuring the mass of a small amount of solid, which comprises:
a coring tube; a function generator; a piezoelectric actuator affixed to the coring tube, a laser aligned with the coring tube.
- 35. A method for measuring the mass of a small amount of solid, which comprises:
attracting dielectric particles to an electrode by imposing a non-uniform electric field; generating a voltage signal; applying the voltage signal to a piezoelectric actuator affixed to the electrode; and measuring the displacement of the electrode with a laser.
- 36. The method of claim 35, wherein:
(a) the voltage signal is a swept-sine signal; or (b) the frequency of the applied voltage signal is between 3.6 kHz and 4.0 kHz.
- 37. An apparatus for measuring the mass of a small amount of solid, which comprises:
an electrode; a function generator; a piezoelectric actuator affixed to the electrode; and a laser aligned with the electrode.
RELATED APPLICATIONS
[0001] This application claims priority under 35 USC 119(e) to U.S. Provisional Application No. 60/423,377, filed Nov. 4, 2002, U.S. Provisional Application No. 60/424,001, filed Nov. 6, 2002, U.S. Provisional Application No. 60/430,089, filed Dec. 2, 2002, U.S. Provisional Application No. 60/449,554, filed Feb. 24, 2003 and U.S. Provisional Application No. 60/450,285, filed Feb. 27, 2003, all of which are incorporated herein by reference in their entireties.
Provisional Applications (5)
|
Number |
Date |
Country |
|
60423377 |
Nov 2002 |
US |
|
60424001 |
Nov 2002 |
US |
|
60430089 |
Dec 2002 |
US |
|
60449554 |
Feb 2003 |
US |
|
60450285 |
Feb 2003 |
US |