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Title:
POUCH WITH FITMENT AND METHOD OF MAKING SAME
Document Type and Number:
WIPO Patent Application WO/2017/127584
Kind Code:
A4
Abstract:
A sealed, empty pouch, wherein the interior of the pouch is particle and pyrogen free, is made by (i) molding a tubular film including an inner surface and an outer surface, and blowing or otherwise directing micro-filtered air and/or other gas through the tubular film during molding; (ii) flattening the molded tubular film; (iii) sealing the flattened tubular film at spaced locations, cutting the sealed film at the spaced locations, and forming a plurality of empty pouches; (iv) over-molding a fitment to the outer surface of each of a plurality of empty pouches and forming a fluid-tight seal between the fitment and the interior of the pouch; and (v) preventing the collection of particles on the inner surface of each pouch, and the exposure of each such inner surface to an ambient atmosphere throughout steps (i) through (iv).

Inventors:
CHAN JULIAN V (US)
PY DANIEL (US)
Application Number:
PCT/US2017/014198
Publication Date:
September 08, 2017
Filing Date:
January 19, 2017
Export Citation:
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Assignee:
PY DR INST LLC (US)
International Classes:
B65B55/06; A61J1/10; B29C53/06; B65B3/02; B65B55/04; B65B55/24; B65D75/58
Attorney, Agent or Firm:
GIARRATANA, Mark, D. et al. (US)
Download PDF:
Claims:
AMENDED CLAIMS

received by the International Bureau on 24 July 2017 (24.07.2017)

CLAIMS

What is claimed is:

1. A method comprising the following steps:

(i) molding a tubular film including an inner surface and an outer surface, and blowing or otherwise directing micro-filtered air and/or other gas through the tubular film during molding;

(ii) flattening the molded tubular film;

(iii) sealing the flattened tubular film at spaced locations, cutting the film, and forming at least one empty pouch;

(iv) over-molding a fitment to the empty pouch and forming a fluid-tight seal between the fitment and pouch; and

(v) preventing the collection of one or more of particles or pyrogens on the inner surface of the pouch, and the exposure of the inner surface to an ambient atmosphere throughout steps (i) through (iv).

2. A method as defined in claim 1 , wherein the molding includes blown film extrusion molding or blown film co-extrusion molding the tubular film, and blowing or otherwise introducing a flow of micro-filtered air and/or other gas through the interior of an extrusion head and the tubular film.

3. A method as defined in claim 1 or 2, wherein at least an inner surface of the tubular film is at bactericidal or sterilization temperature during step (i).

4. A method as defined in any of the preceding claims, further comprising blowing or otherwise directing micro-filtered air and/or other gas toward and/or through an opening to a mold for over-molding the fitment to the pouch.

5. A method as defined in any of the preceding claims, further comprising forming the pouch with a pouch aperture in an edge portion thereof and in fluid communication with an interior chamber of the pouch, and over-molding the fitment to the pouch and forming a fluid- tight seal between the fitment and pouch about the pouch aperture.

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6. A method as defined in claim 5, further comprising over-molding a septum onto the fitment and in fluid communication with the pouch aperture.

7. A method as defined in claim 6, further comprising moving a mold containing the fitment over-molded onto the pouch from a first molding station to a second molding station, and over-molding the septum onto the fitment in the second molding station.

8. A method as defined in claim 6 or 7, further comprising over-molding a septum onto a hinged portion of the fitment and forming a one-piece or integral fitment and septum.

9. A method as defined in claim 8, further comprising moving the hinged septum of the fitment into an at least partially closed position and preventing exposure of the inner surfaces of the septum and fitment to the ambient atmosphere.

10. A method as defined in claim 9, further comprising opening the mold, and upon opening the mold, (i) actuating a cam or other actuator to move the hinged portion of the fitment or (ii) otherwise automatically moving the hinged portion of the fitment, into the at least partially closed position.

11. A method as defined in any of claims 1 to 6, further comprising over-molding the fitment in a first mold cavity, molding a septum in a second mold cavity, moving at least one of the first or second mold cavities toward the other, assembling the septum and fitment, and forming a sealed, empty pouch.

12. A method as defined in claim 1 1 , further comprising rotating or otherwise moving at least one of the first or second molds to align the septum and fitment, moving at least one of the aligned septum or fitment toward the other to assemble the septum and fitment, and de- molding the sealed, empty pouch.

13. A method as defined in claim 1 1 or 12, further comprising directing an overpressure of micro-filtered air and/or other gas into or through an open area of the molds during assembly of the septum and fitment.

14. A method as defined in any of the preceding claims, wherein step (i) further includes molding a multiple layer tubular film including an inner layer defining a first melting

60 temperature and an outer layer defining a second melting temperature, and the first melting temperature of the inner layer is higher than the second melting temperature of the outer layer.

15. A method as defined in claim 14, further including during step (iv) at least partially melting the outer layer of the tubular film and thermally bonding the fitment thereto, but not melting the inner layer of the tubular film and thereby maintaining a separateness between the opposing inner surfaces of the inner layer at the over-molded fitment.

16. A method as defined in any of the preceding claims, wherein step (iii) includes thermally sealing and cutting the tubular film.

17. A method as defined in claim 16, wherein the cutting occurs substantially simultaneously with, or immediately upon, sealing.

1 8. A method as defined in claim 16 or 17, wherein the thermal sealing is performed with one or more of an impulse heat sealer, a continuous heat sealer, a hot bar heat sealer, a hot wire sealer, an induction sealer, and an ultrasonic welder or sealer.

19. A method as defined in any of claims 5 to 10, wherein the pouch aperture is formed prior to insertion of the pouch into the mold for over-molding the fitment thereto, or is formed with the pouch in the mold prior to over-molding the fitment thereto.

20. A method as defined in claim 19, further comprising maintaining the pouch in a flattened condition during forming the pouch aperture, and/or directing an over-pressure of micro-filtered air or other gas onto the pouch during formation of the pouch aperture.

21. A method as defined in any of claims 1 to 4, further including molding a fitment including a base that is over-molded to the outer surface of the pouch and extends along or about a periphery of a pouch aperture, and a port extending from the base and defining a fitment aperture in fluid communication with the pouch aperture.

22. A method as defined in claim 21 , wherein a junction of the base and port defines a reduced cross-sectional thickness to allow flexing of the base and/or port relative to the other.

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23. A method as defined in any of claims 1 to 4, further including forming the pouch with a pouch aperture in an edge portion thereof and in fluid communication with an interior chamber of the pouch, inserting a core pin into the pouch aperture, and over-molding the fitment to the pouch and forming a fluid-tight seal between the fitment and pouch about the pouch aperture.

24. A method as defined in claim 23, further including (i) directing filtered or sterile gas into the pouch aperture to facilitate opening the pouch aperture and introducing the core pin therein, and/or (ii) engaging the outer surface of the pouch at or adjacent to the pouch aperture to facilitate opening the pouch aperture and introducing the core pin therein.

25. A method as defined in claims 23 or 24, further including over-molding an elastomeric fitment about the pouch aperture.

26. A method as defined in claim 25, wherein the elastomeric fitment includes a base over-molded to the outer surface of the pouch, and a penetrable septum in fluid communication with the pouch aperture.

27. A method as defined in claim 26, wherein the fitment includes a septum support, and the method further includes over-molding the septum to the septum support.

28. A method as defined in claim 26 or 27, further including substantially simultaneously over-molding the septum and base of the fitment.

29. A method as defined in any of claims 23 to 28, further including withdrawing the core pin through an aperture in the fitment, and then sealing the fitment aperture.

30. A method as defined in any of claims 23 to 29, further comprising sealing an edge portion of the pouch at spaced locations relative to each other and defining the pouch aperture therebetween.

31. A method as defined in claim 30, further comprising sealing the edge portion of the pouch with a plurality of gaps in the sealed edge portion laterally spaced relative to each other, wherein each gap defines a respective pouch aperture.

32. A sealed, empty pouch, wherein the interior of the pouch is one or more of particle free and pyrogen free, made in accordance with the following method:

(i) molding a tubular film including an inner surface and an outer surface, and blowing or otherwise directing micro-filtered air and/or other gas through the tubular film during molding;

(ii) flattening the molded tubular film;

(iii) sealing the flattened tubular film at spaced locations, cutting the sealed film, and thereby forming an empty pouch;

(iv) over-molding a fitment to the empty pouch; and

(v) preventing the collection of one or more of particles or pyrogens on the inner surface of the pouch, and the exposure of the inner surface to ambient atmosphere throughout steps (i) through (iv).

33. A pouch comprising:

a tubular film including an inner surface and an outer surface, a first end marginal edge portion extending from approximately one side of the pouch to another side of the pouch, and a second end marginal edge portion located on an opposite end of the pouch relative to the first end marginal edge portion and extending from approximately one side of the pouch to another side of the pouch, wherein opposing surfaces of the tubular film are sealed to each other at the first end and second end marginal edge portions, and define an interior chamber between opposing inner surfaces of the tubular film; and the first or second marginal edge portion defines a pouch aperture in fluid communication with the interior chamber; and

a fitment over-molded to the outer surface along a periphery of the pouch aperture, wherein the outer surface is at least partially melted and bonded to the fitment and thereby forms a fluid-tight seal between the fitment and outer surface about the pouch aperture.

34. A pouch as defined in claim 33, wherein the interior chamber of the pouch (i) is hermetically sealed with respect to the ambient atmosphere; (ii) is aseptic; (iii) is sterile; (iii) is particle free; (iv) is pyrogen free; and/or (vi) extends from the first end to the second end, and from one side to another side of the pouch.

35. A pouch as defined in claim 33 or 34, wherein the fitment includes a base over- molded to the outer surface and extending along or about the periphery of the pouch aperture, and a port extending from the base and defining a fitment aperture in fluid communication with the pouch aperture.

36. A pouch as defined in claim 35, wherein a junction of the base and port defines the reduced cross-sectional thickness to allow flexing of the base and/or port relative to the other.

37. A pouch as defined in claim 35 or 36, wherein the fitment includes a septum support and an elastic septum over-molded to the septum support.

38. A pouch as defined in claim 37, wherein the septum support is movable between a first position for over-molding the septum thereto, and a second position for moving the over- molded septum into the fitment aperture to at least partially close the fitment aperture and prevent exposure of the interior surfaces of the septum and fitment aperture to the ambient atmosphere.

39. A pouch as defined in claim 37 or 38, wherein the fitment includes a hinge that movably connects the septum support to the fitment.

40. A pouch as defined in any of claims 33 to 36, wherein the fitment includes a septum over-molded thereto and hermetically sealing the fitment and pouch aperture with respect to ambient atmosphere, the fitment is penetrable by a needle or other injection member for penetrating the septum and sterile filling a substance therethrough into the interior chamber, and the resulting penetration aperture in the septum is resealable by applying one or more of heat, radiation, liquid sealant, hot melt sealant or adhesive, or mechanical closure thereto.

41. A pouch as defined in claim 40, further including a closure overlying the septum and forming a fluid-tight seal between a penetrated septum and the ambient atmosphere.

42. A pouch as defined in claim 41 , wherein the closure is formed of a substantially inflexible or rigid hot-melt adhesive sealant overlying the penetrated septum and bonded to a septum support extending about a periphery of the septum.

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43. A pouch as defined in claim 41 or 42 wherein the closure substantially conforms to the shape or morphology of the septum at the interface therebetween, but is not bonded thereto.

44. A pouch as defined in any of claims 33 to 43, wherein the tubular film is a multiple layer tubular film including an inner layer and an outer layer, the inner layer of the tubular film defines a first melting temperature and the outer layer of the tubular film defines a second melting temperature that is less than the first melting temperature, the outer layer of the tubular film is at least partially melted and thermally bonded to the fitment, and the inner layer of the tubular film is not melted and does not form the bond with the fitment to thereby maintain separation between opposing inner surfaces of the inner layer at the interior chamber.

45. A pouch as defined in claim 33 or 34, wherein the pouch aperture extends through an end edge portion of the pouch, and a fitment base extends over the respective end edge portion and over opposite sides of the pouch relative to each other.

46. A pouch as defined in claim 45, wherein the fitment is formed of an elastomeric material and includes an elastomeric base over-molded to the outer surface of the pouch, and an elastomeric, penetrable septum in fluid communication with the pouch aperture.

47. A pouch as defined in claim 33 or 34, wherein the fitment includes a base over- molded to the film about the pouch aperture, the base includes a first side extending inwardly from an edge portion on one side of the pouch, and a second side extending inwardly from the edge portion on a second side of the pouch opposite the first side of the pouch, wherein the first and second sides of the fitment base are movable with the respective sides of the pouch attached thereto and relative to each other.

48. A pouch as defined in any of claims 33 to 47, wherein the pouch includes sealed edge portions laterally spaced relative to each other and defining the pouch aperture at the unsealed edge portion therebetween.

49. A pouch as defined in claim 48, wherein the sealed edge portion defines a tab extending laterally from the sealed edge, a first side located on one side of the tab, a second side

65 located on an opposite side of the tab, and a distal edge extending between the first and second edges, and the pouch aperture extends through the distal edge of the tab.

50. A pouch as defined as in claim 49, wherein the first side of the tab is sealed, and the second side of the tab is unsealed for allowing passing of a core pin or portion thereof through the opposing sides of the unsealed edge for molding the fitment or a portion thereof to the tab.

51 . A pouch as defined in claim 49 or 50, wherein the base of the fitment extends over and about the first and second sides of the tab, and forms a fluid-tight seal between the fitment and tab that extends substantially throughout the periphery of the tab.

52. A pouch as defined in any of claims 33 to 51 , further comprising a device- receiving edge portion extending laterally from a respective edge of the interior chamber of the pouch; and a sealed portion extending between and separating the interior chamber from the device-receiving edge portion; wherein the sealed portion is defined by opposing layers of the film sealed to each other within the sealed portion.

53. A pouch as defined in claim 52, further comprising an identification device received within the device-receiving edge portion selected from the group including one or more of an RFID tag, a radiation dosimeter, or a label including an RFID tag and/or a radiation dosimeter mounted thereon.

54. A pouch as defined in any of claims 33 to 53, wherein the pouch defines a first interior chamber and a second interior chamber, and a sealed portion extending between the first and second interior chambers.

55. A pouch as defined in claim 54, wherein the sealed portion defines a frangible seal.

56. A pouch as defined in claims 54 or 55, further comprising a first pouch aperture in fluid communication with the first interior chamber, a second pouch aperture in fluid communication with the second interior chamber, a first fitment over-molded to the outer surface

66 along a periphery of the first pouch aperture, and a second fitment over-molded to the outer surface along a periphery of the second pouch aperture.

57. A pouch as defined in claim 56, further comprising a third pouch aperture in fluid communication with the second interior chamber, and a third fitment over-molded to the outer surface along a periphery of the third pouch aperture, wherein the second and third fitments are located on substantially opposite sides of the pouch relative to each other.

58. A method comprising the following steps:

(i) penetrating an elastic septum of a device with a needle or other injection member;

(ii) introducing a substance through the needle or other injection member and into a sealed chamber in fluid communication with the elastic septum;

(iii) withdrawing the needle or other injection member from the septum;

(iv) sealing a resulting hole in the septum by introducing a liquid hot-melt adhesive sealant onto the septum and covering the septum and the resulting hole with the liquid hot-melt sealant; and

(iv) allowing the liquid hot-melt sealant to cool, transition from a liquid to a solid, and form a substantially inflexible closure overlying the septum.

59. A method as defined in claim 58, further comprising heating the liquid hot-melt sealant to a bactericidal temperature, applying the liquid hot-melt sealant onto the septum at the bactericidal temperature, and sterilizing the interface between the hot-melt sealant closure and the septum.

60. A method as defined in claim 58 or 59, further comprising fixedly bonding the liquid hot-melt sealant to a septum support extending about a periphery of the septum, and forming a fluid-tight seal between the septum and ambient atmosphere.

61. A pouch as defined in claim 38, wherein, in the second position, the septum forms a dry compression seal with the fitment aperture.

62. A pouch as defined in claim 38 or 61, wherein, in the second position, the septum support is secured in the fitment aperture by a snap-fit connection.

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63. A method as defined in any one of claims 1 to 5, further comprising over-molding a septum onto a septum support, and attaching the septum support with the over-molded septum to the fitment at a port or aperture of the fitment in fluid communication with the pouch aperture, thereby at least partially closing the fitment port or aperture and preventing exposure of interior surfaces of the septum and fitment to the ambient atmosphere.

64. A method as defined in claim 63, wherein the attaching step comprises forming a dry compression seal between the septum and the fitment port or apertureto hermetically seal the fitment port or aperture.

65. A method as defined in one of claims 63 or 64, wherein the attaching step comprises securing the septum support to the fitment port or aperture by a snap-fit connection.

66. A method as defined in claim 27, further comprising attaching the septum support with the over-molded septum to the fitment at a port or aperture of the fitment in fluid

communication with the pouch aperture, thereby at least partially closing the fitment port or aperture with respect to ambient atmosphere.

67. A method as defined in claim 66, wherein the attaching step comprises forming a dry compression seal between the septum and the fitment aperture or port to hermetically seal the fitment port or aperture.

68. A method as defined in claim 66 or 67, wherein the attaching step comprises securing the septum support to the fitment port or apertureby a snap-fit connection.

69. A method comprising the following steps:

(i) forming or providing a pouch with a pouch aperture in an edge portion thereof and in fluid communication with an interior chamber of the pouch;

(ii) sealing a fitment to the pouch at the pouch aperture and forming a fluid-tight seal between the fitment and the pouch along a periphery of the pouch aperture, the fitment including a fitment port or aperture in fluid communication with the pouch aperture;

(iii) attaching a septum onto a septum support; and

(iv) snap-fitting the septum support with the septum to the fitment at the fitment port or aperture by a snap-fit connection, thereby at least partially closing the fitment port or aperture

68 with respect to ambient atmosphere with the septum in fluid communication with the pouch aperture.

70. A method as defined in claim 69, wherein step (i) includes forming the pouch from a tubular film, sealing the flattened tubular film at spaced locations, cutting the film, and forming the pouch from the cut film.

71. A method as defined in claim 69 or 70, wherein the septum is over-molded to the septum support.

72. A method as defined in one of claims 69-71, wherein step (ii) includes heat- sealing the fitment and the pouch.

73. A method as defined in one of claims 69-72, wherein the pouch aperture is formed prior to sealing the fitment thereto.

74. A method as defined in one of claims 69-73, wherein step (ii) comprises forming a continuous interface seal between the fitment and the pouch.

75. A method as defined in one of claims 69-74, further comprising, prior to step (ii), forming the fitment in a mold, and removing the fitment from the mold.

76. A method as defined in one of claims 72-75, further including, during step (ii), at least partially melting material of the pouch at an interface of the pouch and the fitment.

77. A method as defined in one of claims 69-76, wherein step (iv) includes forming a dry compression seal between the septum and the fitment port or aperture to hermetically seal the fitment port or aperture.

78. A method as defined in one of claims 69-77, wherein step (iv) includes fully closing and hermetically sealing the fitment port or aperture with respect to ambient atmosphere.

79. An apparatus comprising:

(i) a pouch defining an interior chamber and a pouch aperture in an edge portion thereof and in fluid communication with the interior chamber;

69 (ii) a fitment including a port or aperture in fluid communication with the pouch aperture, wherein the fitment is sealed to the pouch along a periphery of the pouch aperture forming a fluid-tight seal between the fitment and pouch; and

(iii) a septum support onto which a septum is attached, wherein the septum support with the septum is attached to the fitment at the fitment port or aperture by a snap-fit connection to at least partially close the fitment port or aperture with respect to ambient atmosphere, and the septum is in fluid communication with the pouch aperture.

80. An apparatus as defined in claim 79, wherein the septum defines a dry compression seal between the septum and the fitment port or aperture between the septum and the fitment port or aperture to hermetically seal the fitment port or aperture.

81. An apparatus as defined in one of claims 79-80, wherein the septum is penetrable by a needle or other injection member for sterile filling a substance therethrough into the interior chamber, and the resulting penetration aperture in the septum is resealable by applying one or more of heat, radiation, liquid sealant, hot melt sealant or adhesive, or a mechanical closure thereto.

82. An apparatus as defined in one of claims 79-81, wherein the pouch is defined by a tubular film, a first end marginal edge portion extending from approximately one side of the pouch to another side of the pouch, and a second end marginal edge portion located on an opposite end of the pouch relative to the first end marginal edge portion and extending from approximately one side of the pouch to another side of the pouch, wherein opposing surfaces of the tubular film are sealed to each other at the first end and second end marginal edge portions, and define the interior chamber between opposing surfaces of the tubular film; and the first or second marginal edge portion defines the pouch aperture.

83. A pouch as defined in one of claims 79-82, wherein the fitment and the pouch are heat sealed.

84. A pouch as defiend in claim 83, wherein the heat seal between the fitment and the pouch defines a continuous interface seal.

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85. A pouch as defined in one of claims 79-84, wherein the septum is over-molded to the septum support.

86. A pouch as defined in one of claims 79-85, wherein the septum support and septum fully close and hermetically seal the fitment port or aperture with respect to ambient atmosphere.

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