WO2005118052A2 - Infusion apparatus - Google Patents

Infusion apparatus Download PDF

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Publication number
WO2005118052A2
WO2005118052A2 PCT/US2005/018495 US2005018495W WO2005118052A2 WO 2005118052 A2 WO2005118052 A2 WO 2005118052A2 US 2005018495 W US2005018495 W US 2005018495W WO 2005118052 A2 WO2005118052 A2 WO 2005118052A2
Authority
WO
WIPO (PCT)
Prior art keywords
fluid
flow
flow control
outer housing
reservoir
Prior art date
Application number
PCT/US2005/018495
Other languages
French (fr)
Other versions
WO2005118052A3 (en
Inventor
Kriesel S. Marshall
Original Assignee
Marshall Kriesel S
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Marshall Kriesel S filed Critical Marshall Kriesel S
Priority to EP05755527A priority Critical patent/EP1758639A4/en
Publication of WO2005118052A2 publication Critical patent/WO2005118052A2/en
Publication of WO2005118052A3 publication Critical patent/WO2005118052A3/en

Links

Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/14Infusion devices, e.g. infusing by gravity; Blood infusion; Accessories therefor
    • A61M5/142Pressure infusion, e.g. using pumps
    • A61M5/145Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons
    • A61M5/148Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons flexible, e.g. independent bags
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/14Infusion devices, e.g. infusing by gravity; Blood infusion; Accessories therefor
    • A61M5/142Pressure infusion, e.g. using pumps
    • A61M5/14244Pressure infusion, e.g. using pumps adapted to be carried by the patient, e.g. portable on the body
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/14Infusion devices, e.g. infusing by gravity; Blood infusion; Accessories therefor
    • A61M5/142Pressure infusion, e.g. using pumps
    • A61M5/145Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons
    • A61M2005/14506Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons mechanically driven, e.g. spring or clockwork
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2205/00General characteristics of the apparatus
    • A61M2205/02General characteristics of the apparatus characterised by a particular materials
    • A61M2205/0244Micromachined materials, e.g. made from silicon wafers, microelectromechanical systems [MEMS] or comprising nanotechnology
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2205/00General characteristics of the apparatus
    • A61M2205/75General characteristics of the apparatus with filters
    • A61M2205/7545General characteristics of the apparatus with filters for solid matter, e.g. microaggregates
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2207/00Methods of manufacture, assembly or production
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M39/00Tubes, tube connectors, tube couplings, valves, access sites or the like, specially adapted for medical use
    • A61M39/22Valves or arrangement of valves
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/14Infusion devices, e.g. infusing by gravity; Blood infusion; Accessories therefor
    • A61M5/141Infusion devices, e.g. infusing by gravity; Blood infusion; Accessories therefor with capillaries for restricting fluid flow
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/178Syringes
    • A61M5/24Ampoule syringes, i.e. syringes with needle for use in combination with replaceable ampoules or carpules, e.g. automatic
    • A61M5/2448Ampoule syringes, i.e. syringes with needle for use in combination with replaceable ampoules or carpules, e.g. automatic comprising means for injection of two or more media, e.g. by mixing

Definitions

  • the present invention relates generally to medicament infusion devices.
  • the invention concerns an improved apparatus for infusing
  • apparatus includes a novel compressible spring energy source, and a
  • novel flow rate control means for precisely controlling the rate of fluid flow from
  • the delivery device while not an active pharmacologic
  • agent may enhance the activity of the drug by mediating its therapeutic
  • hypodermic syringe method of delivery is
  • the present invention is uniquely suited to provide precise, continuous fluid
  • present invention is the provision of novel fill means for filling the reservoir of the
  • present invention is the provision of various fluid flow rate control means
  • the apparatus of the present invention includes a unique,
  • the apparatus of the present invention can be used with minimal
  • devices of the invention can be comfortably and conveniently
  • invention can be used for most I-V chemotherapy and can accurately deliver fluids to the patient in precisely the correct quantities and at extended microfusion rates
  • apparatus can be manufactured at low cost without in any way sacrificing accuracy
  • fluid delivery apparatus generally include: a base assembly, an elastomeric
  • membrane serving as a stored energy means, fluid flow channels for filling and
  • Patent 5,743,879 discloses an injectable medicament dispenser for use in
  • controllably dispensing fluid medicaments such as insulin, anti-infectives,
  • analgesics for example, analgesic, oncolylotics, cardiac drugs biopharmaceuticals, and the like from a
  • the dispenser which is quite dissimilar in
  • Another object of the invention is to provide a small, compact fluid
  • dispenser that includes a housing to which fill vials can be connected for filling the
  • dispenser reservoir with the fluid.
  • Another object of the invention is to provide a dispenser of in which a stored
  • Another object of the invention is to provide a dispenser of the class
  • Another object of the invention is to provide a dispenser that includes
  • Another object of the invention is to provide a fluid dispenser which is
  • Another object of the invention is to provide a fluid dispenser of the class
  • Another object of the invention is to provide a self-contained medicament
  • Another object of the invention is to provide a fluid dispenser as described in
  • Figure 1 is a generally perspective left front view of one embodiment of the
  • medicament infusion apparatus of the present invention for dispensing fluids at a
  • Figure 2 is a generally perspective right front view of the embodiment of the
  • Figure 3 is an enlarged, longitudinal cross-sectional view of the apparatus
  • Figure 4 is an enlarged, cross- sectional view of the area designated as "4" in
  • Figure 5 is a right end view of the apparatus shown in figure 3.
  • Figure 6 is an exploded view of the forward portion of the apparatus shown
  • Figure 7 is a cross-sectional view taken along lines 7-7 of figure 6.
  • Figure 8 is a view taken along lines 8-8 of figure 6.
  • Figure 9 is a cross-sectional view taken along lines 9-9 of figure 8.
  • Figure 10 is a view taken along lines 10-10 of figure 6.
  • Figure 11 is a greatly enlarged cross-sectional view of one form of the rate
  • Figure 12 is an exploded, cross-sectional view of the rate control assembly
  • Figure 13 is a generally perspective, exploded front view of the rate control
  • Figure 14 is a generally perspective, exploded rear view of the rate control
  • Figure 15 is a cross-sectional view taken along lines 15-15 of figure 11.
  • Figure 16 is a view similar to figure 15, but showing an alternate form of
  • Figure 17 is a generally perspective, exploded view of an alternate form of
  • Figure 18 is a generally perspective, exploded view of yet another alternate
  • Figure 19 is a cross sectional view of still another form of the fluid rate
  • Figure 19A is an exploded perspective view of the rate control assembly
  • Figure 19B is a generally diagrammatic, tabular view illustrating various
  • Figure 19C is a generally diagrammatic, tabular view further illustrating
  • Figure 19D is a generally diagrammatic, tabular view further illustrating
  • Figure 19E is a generally diagrammatic, tabular view further illustrating
  • Figure 19F is a generally diagrammatic, tabular view further illustrating
  • Figure 20 is a generally perspective view of an alternate embodiment of the
  • infusion apparatus of the present invention for dispensing fluids at a uniform rate.
  • Figure 21 A is an enlarged, longitudinal cross-sectional view of the forward
  • Figure 2 IB is an enlarged, cross-sectional view of the rear portion of the
  • Figure 21C is an enlarged, cross-sectional view of the area designated as
  • Figure 2 ID is an enlarged, cross-sectional view of the area designated as
  • Figure 2 IE is an enlarged, cross-sectional view of the elastomeric sealing
  • Figure 2 IF is an enlarged, cross-sectional view of the elastomeric sealing
  • Figure 22 is a cross- sectional view similar to figure 21, but showing the
  • Figure 22 A is a cross-sectional view taken along lines 22A- 22A of figure
  • Figure 23 is a cross-sectional view of one of the prefilled medicament shell
  • vials that can be used to fill the fluid reservoir of the apparams shown in figure 21.
  • Figure 24 is a view taken along lines 24-24 of figure 23.
  • Figure 25 is an end view of the apparatus shown in figure 21.
  • Figure 26 is a view taken along lines 26-26 of figure 25.
  • Figure 27 is a cross-sectional view taken along lines 27-27 of figure 2 IB.
  • Figures 28 and 28A when considered together comprise a generally
  • FIG. 29 is a generally perspective, exploded view of one form of the
  • Figure 30 is a fragmentary, front view similar to the front view shown in
  • Figure 31 is a cross-sectional view taken along lines 31-31 of figure 30.
  • Figure 32 is an enlarged, fragmentary, bottom view of the forward portion of
  • Figure 33 is a cross-sectional view taken along lines 33-33 of figure 32 but
  • Figure 34 is a fragmentary, cross-sectional view similar to figure 33 but
  • Figure 35 is a generally perspective, front view of one form of the fluid flow
  • Figure 36 is a generally perspective, exploded front view of the fluid flow
  • Figure 37 is a greatly enlarged, f agmentary cross-sectional view of one of
  • Figure 38 is a generally perspective, rear view of the fluid flow control
  • Figure 39 is a generally perspective, exploded rear view of the fluid flow
  • Figure 40 is a generally perspective view of an alternate form of the flow
  • Figure 40A is a generally perspective view of yet another form of the flow
  • Figure 41 is a front view of the assembly shown in figure 35.
  • Figure 42 is a cross-sectional view taken along lines 42-42 of figure 41.
  • Figure 43 is a view taken along lines 43-43 of figure 42.
  • Figure 44 is a cross-sectional view taken along lines 44-44 of figure 42.
  • Figure 45 is a cross-sectional view taken along lines 45-45 of figure 42.
  • Figure 46 is a generally perspective view of an alternate embodiment of the
  • fluid delivery apparatus of the present invention for dispensing fluids at a uniform
  • Figure 47 is an enlarged, longitudinal cross-sectional view of the
  • Figure 47 A is an enlarged, cross-sectional view of the area designated as
  • Figure 47B is an enlarged, cross-sectional view of the elastomeric sealing
  • Figure 48 is view taken along lines 48-48 of figure 47.
  • Figure 49 is a bottom view of the apparatus shown in figure 47.
  • Figure 50 is an enlarged view of one of the fill vial assemblies shown in
  • Figure 50A is a view taken along lines 50A-50A of figure 50.
  • Figure 51 is a generally perspective, exploded view of fluid delivery
  • Figure 52 is cross-sectional view taken along lines 52-52 of figure 47.
  • Figure 53 is a generally perspective view of yet another embodiment of the
  • present invention for dispensing fluids at a uniform rate.
  • Figure 54 is an enlarged, longitudinal cross-sectional view of the
  • Figure 54A is an enlarged, cross-sectional view of the area designated as
  • Figure 54B is an enlarged, cross-sectional view of the elastomeric sealing
  • Figure 55 is a top view of the apparatus shown in figure 54.
  • Figure 56 is cross-sectional view taken along lines 56-56 of figure 54.
  • Figure 57 is a left end view of the apparatus shown in figure 54.
  • Figure 58 is a side view of the vial cover component of the apparatus.
  • Figure 59 is a view taken along lines 59-59 of figure 58.
  • Figure 60 is a generally perspective exploded view of this latest embodiment
  • Figure 61 is an enlarged, longitudinal, cross-sectional view of one of the fill
  • Figure 62 is a cross-sectional view taken along lines 62-62 of figure 61.
  • Figure 63 is an enlarged, longitudinal, cross-sectional view of the other fill
  • Figure 64 is a cross-sectional view taken along lines 64-64 of figure 63.
  • Figure 65 is a cross-sectional view of an alternate form of fill vial assembly
  • Figure 66 is a cross-sectional view taken along lines 66-66 of figure 65.
  • Figure 67 is a generally perspective view of still another embodiment of the
  • medicament infusion apparatus of the present invention for dispensing fluids at a
  • Figure 68 is a bottom plan view of the embodiment of the apparatus shown in figure 67.
  • Figure 69 is a top plan view of the embodiment of the apparatus shown in
  • Figure 70 is a side elevational view of the vial cover portion of the apparatus
  • Figure 71 is a view taken along lines 71-71 of figure 70.
  • Figure 72 is a cross-sectional view taken along lines 72-72 of figure 69,
  • Figure 72A is an enlarged, cross-sectional view of the area designated as
  • Figure 72B is an enlarged, cross-sectional view of the elastomeric sealing
  • Figure 72 C is an enlarged, cross-sectional view of the area designated as
  • Figure 72D is an enlarged, cross-sectional view of the elastomeric sealing
  • Figure 73 is a right end view of the apparatus shown in figure 67.
  • Figure 74 is a left end view of the apparatus shown in figure 67.
  • Figure 75 is a cross-sectional view taken along lines 75-75 of figure 72.
  • Figure 76 is a cross-sectional view taken along lines 76-76 of figure 72.
  • Figure 77 is a cross-sectional view taken along lines 77-77 of figure 72.
  • Figure 78 is a generally perspective, front view of the flow rate control
  • Figure 79 is a rear view of the forward most rate control plate of the flow
  • control means shown in figure 81 The control means shown in figure 81.
  • Figure 80 is a cross-sectional view taken along lines 80-80 of Fig. 79.
  • Figure 81 is a generally perspective, rear view of the flow rate control means
  • Figure 82A is a generally perspective exploded view of the rear half of
  • Figure 82B is a generally perspective exploded view of the front half of
  • Figure 83 when considered in its entirety, comprises a front view of each of
  • Figure 84 is a rear view of the first, or leftmost rate control plate of the rate
  • control plate assembly shown in figure 81.
  • Figure 84A is a cross-sectional view taken along lines 84A-84A of figure 84.
  • Figure 85 is a side elevational view of the rate control plate assembly shown
  • Figure 81 is a rear view of the outlet manifold component of the assembly
  • Figure 87 is a cross-sectional view taken along lines 87-87 of figure 86.
  • Figure 88 is a front view of the assembly shown in figure 85.
  • Figure 89 is a front view of the first from the left, rate control plate or inlet
  • Figure 90 is a front view of the rate control plate shown in figure 82.
  • Figure 91 is a cross-sectional view taken along lines 91-91 of figure 90.
  • Figure 92 is a front view of the second from the left, rate control plate shown
  • Figure 93 is a rear view of the rate control plate shown in figure 92.
  • Figure 94 is a cross-sectional view taken along lines 94-94 of figure 93.
  • Figure 95 is a fragmentary cross-sectional view of the forward portion of the
  • Figure 95 A is an enlarged, fragmentary cross-sectional view of the upper
  • Figure 95B is an enlarged fragmentary cross-sectional view of the lower
  • Figure 96 is a cross-sectional view taken along lines 96-96 of figure 95.
  • Figure 97 is a cross-sectional view similar to figure 96, but showing the rate
  • control knob rotated to a second position.
  • apparatus here comprises an outer housing 104 having first and second portions
  • outer housing 104 Disposed within outer housing 104 is
  • an inner, expandable housing 110 having a fluid reservoir 112 provided with an
  • Expandable housing 110 for permitting fluid flow from the fluid reservoir. Expandable housing 110,
  • the inner wall of the bellows is provided with a surface
  • This coating 118 can be accomplished by several different
  • this technique allows for any of the following: plasma activation, plasma induced grafting and plasma polymerization of molecular
  • plasma using fluorine-containing molecules may be employed.
  • the drug interface bellows surface may be cleaned with an inert gas
  • a fluorine containing plasma may be used to graft these
  • hydrophilic surface e.g. for
  • cleaning may be done, followed by a plasma polymerization using hydrophilic
  • stored energy means comprises a resiliently deformable, spring 120 that is carried
  • described spring 120 is first more fully compressed by fluid flowing into reservoir
  • member 120 can be constructed in various configurations and from a wide variety
  • spring 120 takes the form of
  • wave springs operate as load bearing devices. They can also take
  • Forming an important aspect of the apparatus of the present invention is fill
  • first portion 106 includes a fluid passageway
  • fluid passageway 122 communicates with a cavity 124 formed within portion 106 of the housing 104. Disposed within cavity 124 is an elastomeric,
  • pierceable septum 126 that comprises a part of one form of the fill means of the
  • Septum 126 is held in position by a bonded retainer 126a and is
  • invention is a novel fluid flow control means that is disposed interiorly of outer
  • This flow control means functions to precisely control the rate of
  • the flow control means comprises a flow
  • control assembly generally designated in the drawings by the numeral 130.
  • this novel flow control assembly here comprises an
  • inlet manifold 132 having an inlet port 134 that is in communication with the outlet
  • outlet manifold 136 as an outlet port 139 that is in communication with the outlet
  • shaped separator plate 138 is filter means here provided as a filter member 142 that
  • Generally disk shaped filter member 142 can be formed from various porous materials
  • Filter number 142 can be bonded or
  • separator plate 138 is provided with standoff ribs
  • filter 142 is preferably encapsulated within an outer metal or plastic casing
  • the flow rate control means or assemblage 130
  • outlet port 139 of the outlet manifold is radially
  • microchannel can take several forms as, for example, those illustrated in figures 15 and 16 of the drawings and generally designated therein by the numerals
  • apparatus of the present invention is dispensing means for dispensing fluid to the
  • this dispensing means comprises an
  • administration set 148 that is connected to the first portion 106 of housing 104 in
  • passageway 152 which is formed in housing portion 106 in the manner best seen in
  • administration line is a conventional gas vent and particulate filter 156.
  • a conventional gas vent and particulate filter 156 Provided at
  • the distal end 150b is a luer connector 158 and cap 158a of conventional
  • means here comprises a control knob assembly 160 that includes a finger gripping
  • control knob assembly 160 is rotatable from a first "on”, or fluid flow position, to a second "off position as
  • control knob assembly is retained in position within a housing 106 by a retainer
  • Shank portion 164 of the control knob assembly includes an axial flow
  • passageway 168 that communicates with the earlier identified outlet flow
  • the flow passageway 168 also a stub passageway 169.
  • the flow passageway 168 also a stub passageway 169.
  • control knob assembly is provided with
  • the reservoir 112 of the bellows component 110 can be filled by
  • filling means which comprises a conventional syringe having a needle adapted to
  • volume indicator member 176 that is carried within a second portion 108 of the
  • vent means any gases trapped within the reservoir will be vented to atmosphere via vent means
  • V mounted in control knob assembly 160.
  • a seal ring 113 (figure 3), prevents
  • administration set can be accomplished by rotating the control knob from the "off
  • housing portion 106 As the fluid flows outwardly of the apparatus due
  • the invention includes a radially outwardly extending indicating finger 176a that is
  • volume indicator window 177 that is provided in a second portion
  • window 177 function to readily indicate to the caregiver the amount of fluid
  • Housing portion 106 includes an
  • inwardly extending ullage portion 180 that functions to ensure that substantially all
  • reservoir 112 can be controllably dispensed to the patient including, by
  • medicaments of various types drugs, pharmaceuticals, hormones,
  • This flow control means can be mounted within housing
  • the flow control means comprises a flow control
  • assembly 180 here comprises a first component or inlet manifold 180a having an
  • inlet port 183 that can be placed in communication with the outlet 116 of the fluid
  • Outlet manifold component 180b has an outlet port 181 that is in
  • Intake manifold 180a has an inner
  • Capillaries 184 have input and output channels 184a that are in
  • Separator plate 181 has an inner surface that is also provided
  • separator plate 181 which is disposed intermediate separator plate 181 and
  • outlet manifold 180b has an inner surface that is provided with a plurality of
  • Capillaries 187 also have larger
  • control assembly are preferably adhesively bonded together. It is to be noted that
  • the rear surfaces of the plates are planar and cooperate with the capillaries to form
  • Thermal bonding may be performed by using a channeled plate and an
  • the two plates are placed in contact with one another confined mechanically and
  • the bonding material or adhesive may
  • thermo-melting adhesives the adhesive material is melted into the two opposed thermo-melting adhesives
  • materials or adhesives may be applied to one of the surfaces of one of the plates.
  • the adhesive is cured by air exposure or via irradiation with a light source.
  • curable bonding materials or adhesives may be elastomeric (e.g. thermoplastic
  • bonding materials may or may not require pressure to seal the channel system.
  • They may also provide closure and sealing to small irregularities in the opposed
  • a channel system may be formed and sealed in cases where two surfaces are
  • a vacuum may be applied to the
  • Bonding may then be accomplished by thermal methods or after
  • This flow control means can also be mounted within
  • housing 104 in place of flow control assembly 130 and functions to precisely
  • the flow control means comprises a bonded-flow
  • Flow control assembly 190 here comprises a first component or inlet
  • manifold 190a having an inlet port 191 that can be placed in communication with
  • outlet manifold 190b that can be interconnected with intake manifold 190a by
  • Outlet manifold 190b has
  • 190a has an inner surface that is provided with a plurality of interconnected imbedded capillaries 196.
  • Capillaries 196 are in communication both with inlet
  • Separator plate 192 has an inner
  • capillaries 196 flows into capillaries 198 via an inlet port 197 and then
  • Separator plate 195 which is disposed intermediate separator plate 192 and
  • outlet manifold 190b has an inner surface that is provided with a plurality of
  • outlet manifold 190b via an outlet port 195a.
  • capillaries 196, 198 As before, by controlling the length, depth and width of capillaries 196, 198
  • the rate of fluid flow flowing outwardly of outlet 194 can be precisely
  • This flow control means can also be
  • the flow control means is configured to precisely control the rate of fluid flow from reservoir 112 toward the patient.
  • the flow control means are configured to precisely control the rate of fluid flow from reservoir 112 toward the patient.
  • Flow control assembly 200 here comprises a first component or inlet
  • manifold 202 having an inlet port 202a that can be placed in communication with
  • Outlet manifold 204 has an outlet port 204a that is in
  • Separator plate 206 has first and
  • Capillaries 214 are in
  • outlet manifold cooperate with the capillaries to form fluid flow channels through
  • Compression springs are open-wound helical springs that exert a load or
  • They may be conical or taper springs, barrel or convex,
  • the ends can be closed and ground, closed but unground, open
  • springs including: Commercial Wire (BS5216 HS3), Music Stainless Steel,
  • Nimonic 90 Round wire, Square and Rectangular sections are also available.
  • Exotic metals and their alloys with special properties can also be used for special
  • Compression springs can also be made from plastic including all
  • springs may be used in light-to-medium duty applications for quiet and corrosion-
  • Multiwave compression springs an example of which is shown as "F" in
  • figure 19C are readily commercially available from sources, such as the Smalley
  • load-bearing devices as load-bearing devices. They can take up play and compensate for dimensional
  • annular discs (some with slotted or fingered configuration) which when loaded in the axial direction, change shape.
  • discs In comparison to other types of springs, disc
  • disc-shaped compression springs include a single or
  • one or more disc springs can be used and also of
  • disc springs include carbon steel, chrome vanadium steel,
  • load/deflection characteristic curve can be designed to produce a wide variety of
  • the slotted part is actually functioning as a
  • the rate of fluid flow flowing outwardly of outlet 204a can be precisely controlled.
  • infusion device of the present invention is there illustrated and generally
  • apparatus here comprises an outer housing 222 having first, second and third
  • outer housing 222 Disposed within outer housing 222 is
  • housing 223, which can be constructed from a metal or plastic material and can
  • a coating of the character previously described comprises a bellows structure having an expandable and compressible, accordion-like, generally
  • annular-shaped sidewall 223a the configuration of which is best seen in figures
  • this important stored energy means comprises a compressively deformable, spring
  • spring member 225 is further compressed from
  • Stored energy member 225 can be constructed from a wide
  • invention is fill means carried by the third portion 222c of outer housing 222 for
  • third portion 222c includes a fluid passageway 226 in communication with inlet
  • fluid passageway 226 communicates with a cavity 227 formed within the third portion 222c of the
  • elastomeric pierceable septum 228 Disposed within cavity 227 is an elastomeric pierceable septum 228 that
  • Septum 228 can be bonded in place and is held in position by a retainer 228a and is
  • Septum 228 can comprise a conventional or a
  • septum 228 can be replaced with a needleless
  • Third portion 222c of housing 222 also includes a first chamber 230 for
  • chamber 234 for telescopically receiving a second medicament containing vial 236.
  • An elongated support 238 is mounted within first chamber 230 and a second
  • elongated support 240 is mounted within second chamber 234.
  • elongated supports 238 and 240 has an integrally threaded end portion 241 and
  • hollow needles 242 has a flow passageway 242a that communicates with fluid
  • elongated support 240 and hollow needles 242 together comprise an alternate form of the fill means of the apparatus of the invention. The method of operation of this
  • invention is a novel flow control means that is connected to first portion 222a of
  • This flow control means functions to precisely control the rate
  • the flow control means comprises a
  • This novel flow control assembly here comprises an ullage defining member 248
  • first portion 248a disposed within inner, expandable housing 223 and a
  • member 248b has a
  • subassembly 250 the character of which will next be described.
  • subassembly 250 which comprises a part of flow control assembly 256, comprises
  • An elastomeric sealing band 253 which has the unique configuration shown in figures 2 IF and 2 IE, prevents leakage between
  • member 256 is uniquely provided with a plurality of elongated flow control
  • the flow channels 260 each having an inlet 260a and an outlet 260b.
  • 260 may be of different sizes, lengths and widths and in alternate configurations as
  • the flow control member shown in figure 40 is identified as 258a, while
  • member 258b is provided with flow channels 250b that are formed in spaced-apart
  • channels may be rectangular in cross-section as illustrated in Fig. 37, or
  • they can be semicircular in cross-section, U-shaped in cross-section,
  • fluid flow passageways each being of different overall length and flow capacity.
  • member 256 receives a tongue 252a provided on casing 252 so as to precisely align the outlets 260b of the flow channels 260 with fluid outlets 254
  • the flow control channels 260 can be made by several techniques including
  • embossing process is a lithographic step, which allows a precise pattern of
  • embossing tool are Nickel, Nickel alloys, steel and brass.
  • embossing tool is fabricated, the polymer of choice may be injection molded or
  • channels can also be made by one of a variety of casting
  • liquid plastic resin e.g. a photopolymer
  • a number of materials can be used to fabricate flow control member 256.
  • Thermoplastics embssing & injection molding
  • flow control members 256 can be constructed from microTEC. Additionally, the flow control members 256 can be constructed from microTEC. Additionally, the flow control members 256 can be constructed
  • Selector knob 258, which comprises a part of the selector means of the
  • apparatus of the present invention is dispensing means for dispensing fluid to the
  • this dispensing means comprises an
  • administration set 264 that is connected to the first portion 222a of housing 222 in
  • administration line 265 of the administration set 264 is in communication with
  • the proximal end 265a and the distal end 265b of the administration line is a
  • glass or plastic vial housings has a fluid chamber 272 for containing an injectable
  • Chamber 272 is provided with a first open end 270a and second closed end
  • First open end 270a is sealably closed by closure means here provided in the
  • the plunger is disposed proximate second closed end 270b.
  • vials 232 and 236 can be inserted into chambers
  • Umbrella type check valves 278 function to control
  • microchannels 224a can contain
  • vent means "V” mounted in portion 248b of the ullage member. This vent
  • means here comprises a gas vent 283 that can be constructed of a suitable
  • the stored energy means, or member 225 will tend to return to its initial starting, less compressed configuration thereby controllably
  • vials 232 and 236 can be controllably dispensed to the patient
  • liquid injectable medicaments of various types including, by way of example, liquid injectable medicaments of various types,
  • This distribution means here comprises several radially
  • the filtered fluid will fill passageways 290 and then will flow into the plurality of
  • spiral passageways 260 can flow outwardly of the device via outlets 260b only
  • slot 258b is adapted to receive a spline 256a (figure 36)
  • casing 252 is also
  • selector knob 258 is provided with a
  • indexing cavities 258c by a coil spring 298 that also forms a part of the indexing
  • Coil spring 298 can be compressed by an inward force
  • control knob 258 can be freely rotated to
  • Locking means here provided in the form of
  • a locking member 310 (see figure 29), is also carried by the locking shaft cover
  • indicating finger 282a that is visible
  • Safety disabling means shown here as a disabling shaft 318 that is
  • telescopically movable within a passageway 320 formed within housing portion 222a functions to disable the device (figure 22A, 28A), by occluding the output
  • shaft 318 has a distal end.318a, which, upon
  • the apparatus of this alternate form of the invention comprises an outer
  • housing 332 having first, second and third portions 334, 336, and 338 respectively.
  • an inner, expandable housing 223 Disposed within outer housing 332 is an inner, expandable housing 223 that is of
  • housing 223 includes a fluid reservoir that is provided with an inlet
  • expandable housing 223 comprises a bellows structure having an expandable and compressible, accordion-like side wall 223a, which is suitably
  • stored energy means and here comprises a compressively deformable, wave spring
  • operation member 225 is first more fully compressed by fluid flowing
  • alternate form of the invention comprises fill means carried by the third portion
  • outer housing 332 for filling the reservoir with the fluid to be dispensed.
  • This fill means is also similar to the earlier described fill means, save for the fact
  • vials or cartridges 342 which each are of identical construction.
  • the fill means also includes an alternate fill means that
  • pierceable septum 344 that is disposed within a cavity 346 formed in the third portion 338 of outer housing 332.
  • Elastomeric septum 344 is pierceable
  • third portion 338 of housing 332 includes a pair of
  • spaced-apart chambers 350 for telescopically receiving the medicament containing
  • Each of the fill vial cartridges 342, is of the generally conventional
  • Each fill vial has an open first end 342a and a second end that is closed by a
  • each chamber 350 Mounted proximate the inboard end of each chamber 350 is a hollow needle
  • each vial reservoir 360 Disposed within each vial reservoir 360 is a plunger 366 that is moved by a
  • each of the elongated supports 354 engages a
  • plungers move inwardly of their respective vial reservoirs, the fluid contained in
  • valve 368 mounted within third housing portion 338, into a stub passageway 370,
  • the apparatus of this latest form of the invention also includes flow control
  • This flow control means is connected to first portion 334 of outer
  • housing 332 and comprises an ullage defining member 370 having a first portion
  • the flow control means includes a flow control subassembly that
  • control subassembly 250 is of the configuration shown in figures 35 through
  • apparatus of this latest form of the invention is dispensing means for dispensing
  • This dispensing means is identical in construction and
  • the fluid will flow into a fluid passageway 376 formed in the first portion
  • filter means shown here as a filter 286 that is identical to that previously described.

Abstract

A compact fluid dispenser for use in controllably dispensing fluid medicaments, such as, antibiotics, oncolytics, hormones, steroids, blood clotting agents, analgesics, and like medicinal agents from prefilled containers at a uniform rate. The dispenser uniquely includes a stored energy source that is provided in the form of a substantially constant-force compressible-expandable wave spring that provides the force necessary to continuously and uniformly expel fluid from the device reservoir. The device further includes a fluid flow control assembly that precisely controls the flow of medicament solution to the patient.

Description

MARSHALL S. KRIESE .. .
INFUSION APPARATUS
S P E C I F I C A T I O N
Background of the Invention
Field of the Invention
The present invention relates generally to medicament infusion devices.
More particularly, the invention concerns an improved apparatus for infusing
medicinal agents into an ambulatory patient at specific rates over extended periods
of time, which apparatus includes a novel compressible spring energy source, and a
novel flow rate control means for precisely controlling the rate of fluid flow from
the reservoir of the device.
Discussion of the Prior Art
A number of different types of medicament dispensers for dispensing
medicaments to ambulatory patients have been suggested. Many of the devices
seek either to improve or to replace the traditional gravity flow and hypodermic
syringe methods, which have been the standard for delivery of liquid medicaments
for many years.
The prior art gravity flow methods typically involve the use of intravenous
administration sets and the familiar flexible solution bag suspended above the patient. Such gravametric methods are cumbersome, imprecise and require bed
confinement of the patient. Periodic monitoring of the apparatus by the nurse or
doctor is required to detect malfunctions of the infusion apparatus.
Many medicinal agents require an intravenous route for administration thus
bypassing the digestive system and precluding degradation by the catalytic
enzymes in the digestive tract and the liver. The use of more potent medications at
elevated concentrations has also increased the need for accuracy in controlling the
delivery of such drugs. The delivery device, while not an active pharmacologic
agent, may enhance the activity of the drug by mediating its therapeutic
effectiveness. Certain classes of new pharmacologic agents possess a very narrow
range of therapeutic effectiveness, for instance, too small a dose results in no
effect, while too great a dose can result in a toxic reaction.
For those patients that require frequent injections of the same or different
amounts of medicament, the use of the hypodermic syringe method of delivery is
common. However for each injection, it is necessary to first draw the injection
dose into the syringe, then check the dose and, after making certain that all air has
been expelled from the syringe, finally, inject the dose either under bolus or slow
push protocol. This cumbersome and tedious procedure creates an unacceptable
probability of debilitating complications, particularly for the elderly and the infirm. As will be appreciated from the discussion, which follows, the apparatus of
the present invention is uniquely suited to provide precise, continuous fluid
delivery management at a low cost in those cases where a variety of precise dosage
schemes are of utmost importance. An important aspect of the apparatus of the
present invention is the provision of novel fill means for filling the reservoir of the
device using a conventional medicament vials or cartridge containers of various
types having a pierceable septum. Another unique feature of the apparatus of the
present invention is the provision of various fluid flow rate control means,
including an embedded microcapillary multichannel flow rate control means which
enables precise control of the rate of fluid flow of the medicament to the patient.
More particularly, the apparatus of the present invention includes a unique,
adjustable fluid flow rate mechanism which enables the fluid contained within the
reservoir of the device to be precisely dispensed at various selected rates.
The apparatus of the present invention can be used with minimal
professional assistance in an alternate health care environment, such as the home.
By way of example, devices of the invention can be comfortably and conveniently
removably affixed to the patient's body or clothing and can be used for the
continuous infusion of injectable anti-infectives, hormones, steroids, blood clotting
agents, analgesics, and like medicinal agents. Similarly, the devices of the
invention can be used for most I-V chemotherapy and can accurately deliver fluids to the patient in precisely the correct quantities and at extended microfusion rates
over time.
By way of summary, the apparatus of the present invention uniquely
overcomes the drawbacks of the prior art by providing a novel, disposable
dispenser of simple but highly reliable construction. A particularly important
aspect of the apparatus of the present invention resides in the provision of a novel,
self-contained energy source in the form of a compressible-expandable spring
member that provides the force necessary to substantially, uniformly dispense
various solutions from standard prefilled vial containers that can be conveniently
loaded into the apparatus. Because of the simplicity of construction of the
apparatus of the invention, and the straightforward nature of the energy source, the
apparatus can be manufactured at low cost without in any way sacrificing accuracy
and reliability.
With regard to the prior art, one of the most versatile and unique fluid
delivery apparatus developed in recent years is that developed by the present
inventor and described in U.S. Pat. No. 5,205,820. The components of this novel
fluid delivery apparatus generally include: a base assembly, an elastomeric
membrane serving as a stored energy means, fluid flow channels for filling and
delivery, flow control means, a cover, and an ullage which comprises a part of the
base assembly. Another prior art patent issued to the present applicant, namely United States
Patent 5,743,879, discloses an injectable medicament dispenser for use in
controllably dispensing fluid medicaments such as insulin, anti-infectives,
analgesics, oncolylotics, cardiac drugs biopharmaceuticals, and the like from a
prefilled container at a uniform rate. The dispenser, which is quite dissimilar in
construction and operation from that of the present invention, includes a stored
energy source in the form of a compressively deformable, polymeric elastomeric
member that provides the force necessary to controllably discharge the
medicament from a prefilled container which is housed within the body of the
device. After having been deformed, the polymeric, elastomeric member will
return to its starting configuration in a highly predictable manner.
Another important prior art fluid delivery device is described in the United
States patent No. 6,063,059 also issued to the present inventor. This device, while
being of a completely different construction embodies a compressible-expandable
stored energy source somewhat similar to that used in the apparatus of the present
invention.
Still another prior art fluid delivery device, in which the present inventor is
also named as an inventor, is described in United States patent No. 6,086,561. This
latter patent incorporates a fill system that makes use of conventional vials and
cartridge medicament containers. Summary of the Invention
It is an object of the present invention to provide a compact fluid dispenser
for use in controllably dispensing fluid medicaments, such as, antibiotics,
oncolytics, hormones, steroids, blood clotting agents, analgesics, and like
medicinal agents from prefilled containers at a uniform rate.
Another object of the invention is to provide a small, compact fluid
dispenser that includes a housing to which fill vials can be connected for filling the
dispenser reservoir with the fluid.
Another object of the invention is to provide a dispenser of in which a stored
energy source is provided in the form of a compressible-expandable spring
member that provides the force necessary to continuously and substantially
uniformly expel fluid from the device reservoir.
Another object of the invention is to provide a dispenser of the class
described which includes a fluid flow control assembly that precisely controls the
flow of the medicament solution to the patient.
Another object of the invention is to provide a dispenser that includes
precise variable flow rate selection. Another object of the invention is to provide a fluid dispenser which is
adapted to be used with conventional prefilled drug containers to deliver beneficial
agents therefrom in a precise and sterile manner.
Another object of the invention is to provide a fluid dispenser of the class
described which is compact, lightweight, is easy for ambulatory patients to use, is
fully disposable, and is extremely accurate so as to enable the infusion of precise
doses of medicament over prescribed periods of time.
Another object of the invention is to provide a device of the character
described which embodies a novel fluid volume indicator that provides a readily
discernible visual indication of the volume of fluid remaining in the device
reservoir
Another object of the invention is to provide a self-contained medicament
dispenser which is of very simple construction and yet extremely reliable in use.
Another object of the invention is to provide a fluid dispenser as described in
the preceding paragraphs which is easy and inexpensive to manufacture in large
quantities. Brief Description of the Drawings
Figure 1 is a generally perspective left front view of one embodiment of the
medicament infusion apparatus of the present invention for dispensing fluids at a
uniform rate.
Figure 2 is a generally perspective right front view of the embodiment of the
medicament infusion apparatus shown in figure 1.
Figure 3 is an enlarged, longitudinal cross-sectional view of the apparatus
shown in figure 1.
Figure 4 is an enlarged, cross- sectional view of the area designated as "4" in
figure 3.
Figure 5 is a right end view of the apparatus shown in figure 3.
Figure 6 is an exploded view of the forward portion of the apparatus shown
in figure 3.
Figure 7 is a cross-sectional view taken along lines 7-7 of figure 6.
Figure 8 is a view taken along lines 8-8 of figure 6. Figure 9 is a cross-sectional view taken along lines 9-9 of figure 8. Figure 10 is a view taken along lines 10-10 of figure 6. Figure 11 is a greatly enlarged cross-sectional view of one form of the rate
control assembly of the invention. Figure 12 is an exploded, cross-sectional view of the rate control assembly
shown in figure 11.
Figure 13 is a generally perspective, exploded front view of the rate control
assembly shown in figure 11.
Figure 14 is a generally perspective, exploded rear view of the rate control
assembly shown in figure 11.
Figure 15 is a cross-sectional view taken along lines 15-15 of figure 11.
Figure 16 is a view similar to figure 15, but showing an alternate form of
flow rate control component.
Figure 17 is a generally perspective, exploded view of an alternate form of
flow rate control assembly.
Figure 18 is a generally perspective, exploded view of yet another alternate
form of the fluid flow rate assembly of the invention.
Figure 19 is a cross sectional view of still another form of the fluid rate
control assembly of the invention.
Figure 19A is an exploded perspective view of the rate control assembly
shown in figure 19.
Figure 19B is a generally diagrammatic, tabular view illustrating various
types of springs that can be used as the stored energy source of the invention. Figure 19C is a generally diagrammatic, tabular view further illustrating
various types of springs that can be used as the stored energy source of the
invention.
Figure 19D is a generally diagrammatic, tabular view further illustrating
various types of springs that can be used as the stored energy source of the
invention.
Figure 19E is a generally diagrammatic, tabular view further illustrating
various types of springs that can be used as the stored energy source of the
invention.
Figure 19F is a generally diagrammatic, tabular view further illustrating
various types of springs that can be used as the stored energy source of the
invention.
Figure 20 is a generally perspective view of an alternate embodiment of the
infusion apparatus of the present invention for dispensing fluids at a uniform rate.
Figure 21 A is an enlarged, longitudinal cross-sectional view of the forward
portion of the apparatus shown in figure 20.
Figure 2 IB is an enlarged, cross-sectional view of the rear portion of the
apparatus.
Figure 21C is an enlarged, cross-sectional view of the area designated as
21C in figure 21 A. Figure 2 ID is an enlarged, cross-sectional view of the area designated as
21D in figure 21 A.
Figure 2 IE is an enlarged, cross-sectional view of the elastomeric sealing
band shown in 21E in figure 21D.
Figure 2 IF is an enlarged, cross-sectional view of the elastomeric sealing
band shown in figure 21C.
Figure 22 is a cross- sectional view similar to figure 21, but showing the
apparatus in a fluid fill mode.
Figure 22 A is a cross-sectional view taken along lines 22A- 22A of figure
22.
Figure 23 is a cross-sectional view of one of the prefilled medicament shell
vials that can be used to fill the fluid reservoir of the apparams shown in figure 21.
Figure 24 is a view taken along lines 24-24 of figure 23.
Figure 25 is an end view of the apparatus shown in figure 21.
Figure 26 is a view taken along lines 26-26 of figure 25.
Figure 27 is a cross-sectional view taken along lines 27-27 of figure 2 IB.
Figures 28 and 28A, when considered together comprise a generally
perspective, exploded view of the various internal operating components of this
latest form of the apparatus of the invention.
l l Figure 29 is a generally perspective, exploded view of one form of the
indexing means of the invention shown in figure 21 A.
Figure 30 is a fragmentary, front view similar to the front view shown in
figure 25, but better showing the configuration of the indexing means of the
invention.
Figure 31 is a cross-sectional view taken along lines 31-31 of figure 30.
Figure 32 is an enlarged, fragmentary, bottom view of the forward portion of
the apparatus shown in figure 22.
Figure 33 is a cross-sectional view taken along lines 33-33 of figure 32 but
rotated 90° counterclockwise.
Figure 34 is a fragmentary, cross-sectional view similar to figure 33 but
showing the indexing means in a locked position.
Figure 35 is a generally perspective, front view of one form of the fluid flow
control assembly of the apparatus of the invention.
Figure 36 is a generally perspective, exploded front view of the fluid flow
control assembly shown in figure 35.
Figure 37 is a greatly enlarged, f agmentary cross-sectional view of one of
the flow control channels formed in the flow control member shown in the central
portion of figure 36. Figure 38 is a generally perspective, rear view of the fluid flow control
assembly of the apparatus of the invention.
Figure 39 is a generally perspective, exploded rear view of the fluid flow
control assembly shown in figure 38.
Figure 40 is a generally perspective view of an alternate form of the flow
control member of the invention.
Figure 40A is a generally perspective view of yet another form of the flow
control member of the invention.
Figure 41 is a front view of the assembly shown in figure 35.
Figure 42 is a cross-sectional view taken along lines 42-42 of figure 41.
Figure 43 is a view taken along lines 43-43 of figure 42.
Figure 44 is a cross-sectional view taken along lines 44-44 of figure 42.
Figure 45 is a cross-sectional view taken along lines 45-45 of figure 42.
Figure 46 is a generally perspective view of an alternate embodiment of the
fluid delivery apparatus of the present invention for dispensing fluids at a uniform
rate.
Figure 47 is an enlarged, longitudinal cross-sectional view of the
embodiment of the invention shown in figure 46. Figure 47 A is an enlarged, cross-sectional view of the area designated as
47 A in figure 47.
Figure 47B is an enlarged, cross-sectional view of the elastomeric sealing
band shown in figure 47A.
Figure 48 is view taken along lines 48-48 of figure 47.
Figure 49 is a bottom view of the apparatus shown in figure 47.
Figure 50 is an enlarged view of one of the fill vial assemblies shown in
figure 47.
Figure 50A is a view taken along lines 50A-50A of figure 50.
Figure 51 is a generally perspective, exploded view of fluid delivery
apparatus shown in figure 47
Figure 52 is cross-sectional view taken along lines 52-52 of figure 47.
Figure 53 is a generally perspective view of yet another embodiment of the
present invention for dispensing fluids at a uniform rate.
Figure 54 is an enlarged, longitudinal cross-sectional view of the
embodiment of the invention shown in figure 53.
Figure 54A is an enlarged, cross-sectional view of the area designated as
54A in figure 54.
Figure 54B is an enlarged, cross-sectional view of the elastomeric sealing
band shown in figure 54A. Figure 55 is a top view of the apparatus shown in figure 54.
Figure 56 is cross-sectional view taken along lines 56-56 of figure 54.
Figure 57 is a left end view of the apparatus shown in figure 54.
Figure 58 is a side view of the vial cover component of the apparatus.
Figure 59 is a view taken along lines 59-59 of figure 58.
Figure 60 is a generally perspective exploded view of this latest embodiment
of the invention.
Figure 61 is an enlarged, longitudinal, cross-sectional view of one of the fill
vial assemblies shown in figure 54.
Figure 62 is a cross-sectional view taken along lines 62-62 of figure 61.
Figure 63 is an enlarged, longitudinal, cross-sectional view of the other fill
vial assembly of the apparatus of the invention.
Figure 64 is a cross-sectional view taken along lines 64-64 of figure 63.
Figure 65 is a cross-sectional view of an alternate form of fill vial assembly
of the invention.
Figure 66 is a cross-sectional view taken along lines 66-66 of figure 65.
Figure 67 is a generally perspective view of still another embodiment of the
medicament infusion apparatus of the present invention for dispensing fluids at a
uniform rate.
Figure 68 is a bottom plan view of the embodiment of the apparatus shown in figure 67.
Figure 69 is a top plan view of the embodiment of the apparatus shown in
figure 67.
Figure 70 is a side elevational view of the vial cover portion of the apparatus
shown in figure 67.
Figure 71 is a view taken along lines 71-71 of figure 70.
Figure 72 is a cross-sectional view taken along lines 72-72 of figure 69,
Figure 72A is an enlarged, cross-sectional view of the area designated as
72 A in figure 72.
Figure 72B is an enlarged, cross-sectional view of the elastomeric sealing
band shown in figure 72A.
Figure 72 C is an enlarged, cross-sectional view of the area designated as
72C in figure 72.
Figure 72D is an enlarged, cross-sectional view of the elastomeric sealing
band shown in figure 72C.
Figure 73 is a right end view of the apparatus shown in figure 67.
Figure 74 is a left end view of the apparatus shown in figure 67.
Figure 75 is a cross-sectional view taken along lines 75-75 of figure 72.
Figure 76 is a cross-sectional view taken along lines 76-76 of figure 72.
Figure 77 is a cross-sectional view taken along lines 77-77 of figure 72. Figure 78 is a generally perspective, front view of the flow rate control
means of this latest form of the apparatus of the present invention.
Figure 79 is a rear view of the forward most rate control plate of the flow
control means shown in figure 81.
Figure 80 is a cross-sectional view taken along lines 80-80 of Fig. 79.
Figure 81 is a generally perspective, rear view of the flow rate control means
shown in figure 78.
Figure 82A is a generally perspective exploded view of the rear half of
various flow rate control plates that make up the flow rate control plate assembly
of the invention.
Figure 82B is a generally perspective exploded view of the front half of
various flow rate control plates that make up the flow rate control plate assembly
of the invention.
Figure 83, when considered in its entirety, comprises a front view of each of
the rate control plates of the invention shown in figures 82A and 82B.
Figure 84 is a rear view of the first, or leftmost rate control plate of the rate
control plate assembly shown in figure 81.
Figure 84A is a cross-sectional view taken along lines 84A-84A of figure 84.
Figure 85 is a side elevational view of the rate control plate assembly shown
in figure 81 as it appears in an assembled configuration. Figure 86 is a rear view of the outlet manifold component of the assembly
shown in figure 85.
Figure 87 is a cross-sectional view taken along lines 87-87 of figure 86.
Figure 88 is a front view of the assembly shown in figure 85.
Figure 89 is a front view of the first from the left, rate control plate or inlet
manifold shown in figure 82.
Figure 90 is a front view of the rate control plate shown in figure 82.
Figure 91 is a cross-sectional view taken along lines 91-91 of figure 90.
Figure 92 is a front view of the second from the left, rate control plate shown
in figure 82.
Figure 93 is a rear view of the rate control plate shown in figure 92.
Figure 94 is a cross-sectional view taken along lines 94-94 of figure 93.
Figure 95 is a fragmentary cross-sectional view of the forward portion of the
outlet manifold of the flow control means shown sealably mated with the rate
control knob of the apparatus of the invention.
Figure 95 A is an enlarged, fragmentary cross-sectional view of the upper
portion of figure 95.
Figure 95B is an enlarged fragmentary cross-sectional view of the lower
portion of figure 95.
Figure 96 is a cross-sectional view taken along lines 96-96 of figure 95. Figure 97 is a cross-sectional view similar to figure 96, but showing the rate
control knob rotated to a second position.
Description of the Invention
Referring to the drawings and particularly to figures 1 through 10, one
embodiment of the dispensing apparatus of the present invention is there illustrated
and generally designated by the numeral 102. As best seen in figures 1 and 2, the
apparatus here comprises an outer housing 104 having first and second portions
106 and 108 respectively that can be snapped together, adhesively bonded, sonic
bonded or otherwise suitably interconnected. Disposed within outer housing 104 is
an inner, expandable housing 110 having a fluid reservoir 112 provided with an
inlet 114 (figure 3) for permitting fluid flow into the fluid reservoir and an outlet
116 for permitting fluid flow from the fluid reservoir. Expandable housing 110,
which can be constructed from a metal or plastic material, comprises a bellows
structure having an expandable and compressible, accordion-like, annular-shaped
sidewall 110a, the configuration of which is best seen in figures 3 and 4. As best
seen in figure 4, the inner wall of the bellows is provided with a surface
modification or protective coating 118 that is compatible with the fluids contained
within reservoir 112. This coating 118 can be accomplished by several different
processes. One process that is extremely clean, fast and effective is plasma
processing. In particular this technique allows for any of the following: plasma activation, plasma induced grafting and plasma polymerization of molecular
entities on the surface of the bellows. For cases where an inert hydrophobic
interface is desired, plasma using fluorine-containing molecules may be employed.
That is, the drug interface bellows surface may be cleaned with an inert gas
plasma, and subsequently, a fluorine containing plasma may be used to graft these
molecules to the surface. Alternatively, if a hydrophilic surface is desired (e.g. for
drug solutions that are highly corrosive or in oil based solvents) an initial plasma
cleaning may be done, followed by a plasma polymerization using hydrophilic
monomers. Similar drug interface coatings "C" can be provided on other surfaces,
such as fluid passageways, that may be encountered by the drugs that are to be
delivered (see, for example, figure 37).
Disposed within second portion 108 of outer housing 104 is the novel stored
energy means of the invention for acting upon inner expandable housing 110 in a
manner to cause the fluid contained within fluid reservoir 112 to controllably flow
outwardly of the housing. In the present form of the invention, this important
stored energy means comprises a resiliently deformable, spring 120 that is carried
within the second portion 108 of the outer housing. In a manner presently to be
described spring 120 is first more fully compressed by fluid flowing into reservoir
112 and then is controllably expanded to cause fluid flow from the outer housing
through the dispensing means of the invention. As depicted in Figures 19B through 19F and as will be discussed in greater detail hereinafter, stored energy
member 120 can be constructed in various configurations and from a wide variety
of materials including metals and plastics. Preferably, spring 120 takes the form of
a wave spring of the type illustrated in configuration F of figure 19C which is
readily commercially available from sources, such as the Smalley Company of
Lake Zurich, Illinois.
Typically, wave springs operate as load bearing devices. They can also take
up play and compensate for dimensional variations within assemblies. A virtually
unlimited range of forces can be produced whereby loads build either gradually or
abruptly to reach a predetermined working height. This establishes a precise
spring rate in which load is proportional to deflection, and can be tuned to a
particular load requirement.
Typically, a wave spring will occupy an extremely small area for the amount
of work it performs. The use of this product is demanded, but not limited to tight
axial and radial space restraints.
Forming an important aspect of the apparatus of the present invention is fill
means carried by outer housing 104 for filling the reservoir 112 with the fluid to be
dispensed. As best seen in figure 3, first portion 106 includes a fluid passageway
122 in communication with inlet 114 of fluid reservoir 112. Proximate its lower
end 122a, fluid passageway 122 communicates with a cavity 124 formed within portion 106 of the housing 104. Disposed within cavity 124 is an elastomeric,
pierceable septum 126 that comprises a part of one form of the fill means of the
invention. Septum 126 is held in position by a bonded retainer 126a and is
pierceable by the needle of the syringe which contains the medicinal fluid to be
dispensed and which can be used in a conventional manner to fill or partially fill
reservoir 112 via passageway 122 and to recover unused medicament. The fill
means can also be used to add adjuvant drugs.
Forming another very important aspect of the apparatus of the present
invention is a novel fluid flow control means that is disposed interiorly of outer
housing 104. This flow control means functions to precisely control the rate of
fluid flow outwardly from reservoir 112 and toward the patient. In the form of the
invention shown in figures 1 through 19 the flow control means comprises a flow
control assembly generally designated in the drawings by the numeral 130. As
best seen in figures 11 and 12, this novel flow control assembly here comprises an
inlet manifold 132 having an inlet port 134 that is in communication with the outlet
116 of reservoir 112 and an outlet manifold 136 that is interconnected with intake
manifold 132 by means of a separator plate 138. As indicated in figures 11 and 12,
outlet manifold 136 as an outlet port 139 that is in communication with the outlet
of the apparatus and is provided an elongated microchannel 140 that is in
communication both with inlet port 134 and with outlet port 139 of the outlet manifold. ^Disposed intermediate inlet manifold 132 and a generally circular
shaped separator plate 138 is filter means here provided as a filter member 142 that
functions to filter fluid flowing toward outlet port 1 9 of the outlet manifold.
Generally disk shaped filter member 142 can be formed from various porous
materials, including porous poly propolene. Filter number 142 can be bonded or
otherwise suitably fixed in place.
As best seen in figure 13, separator plate 138 is provided with standoff ribs
144 for supporting filter member 142 in the manner shown in Fig. 11. The
assemblage made up of inlet manifold 132, outlet manifold 136, separator plate
138 and filter 142 is preferably encapsulated within an outer metal or plastic casing
146 (see figure 11).
As indicated in figure 11, the flow rate control means, or assemblage 130,
has an axial centerline "CL" with which the inlet port 134 of the inlet manifold 132
is coaxial aligned. However, the outlet port 139 of the outlet manifold is radially
spaced from the axial centerline. With this construction, fluid will flow from
reservoir 112 into inlet port 134, through filter member 142, through a central
opening 138a formed in a separator plate and thence into microchannel 140. By
controlling the length, depth and width of the microchannel 140, the rate of fluid
flow flowing outwardly of outlet 139 can be precisely controlled. In this regard,
the microchannel can take several forms as, for example, those illustrated in figures 15 and 16 of the drawings and generally designated therein by the numerals
140a and 140b.
Turning once again to figures 1, 2 and 3, also forming a part of the infusion
apparatus of the present invention is dispensing means for dispensing fluid to the
patient. In the present form of the invention this dispensing means comprises an
administration set 148 that is connected to the first portion 106 of housing 104 in
the manner shown in the drawings. The proximal end 150a of administration line
150 of the administration set 148 is in communication with an outlet fluid
passageway 152 which is formed in housing portion 106 in the manner best seen in
figure 3. Disposed between the proximal end 150a and the distal end 150b of the
administration line is a conventional gas vent and particulate filter 156. Provided at
the distal end 150b is a luer connector 158 and cap 158a of conventional
construction (figure 1).
To control fluid flow from the outlet 139 of the flow rate control means
toward outlet passageway 152, novel operating means are provided. This operating
means here comprises a control knob assembly 160 that includes a finger gripping
portion of 162 and a generally cylindrically shaped shank portion 164 that is
rotatably received within a bore 166 formed in housing portion 106 (figure 3). O-
rings, generally designated as "O", function to sealably interconnect the various
operating components. As indicated in figure 5, control knob assembly 160 is rotatable from a first "on", or fluid flow position, to a second "off position as
indicated by indicia provided on the forward face of housing portion 106. The
control knob assembly is retained in position within a housing 106 by a retainer
ring 165. Shank portion 164 of the control knob assembly includes an axial flow
passageway 168 that communicates with the earlier identified outlet flow
passageway 152 via a stub passageway 169. The flow passageway 168 also
communicates with outlet 139 of flow rate control assembly 130 when the control
assembly is in the "on" position shown in figure 5. In this position, fluid it can
flow from reservoir 112, through outlet 116, through flow rate control assembly
130, into central passageway 168 of the control knob assembly and then toward the
administration set via passageway 152. As indicated in figures 6 and 8, to guide
the travel of the control knob assembly, the control knob assembly is provided with
a protuberance 170 that travels within a groove 172 provided in the housing
portion 106.
In using the apparatus of the invention, with the control knob assembly in
the "off position, the reservoir 112 of the bellows component 110 can be filled by
filling means which comprises a conventional syringe having a needle adapted to
pierce the pierceable septum 126 which is mounted within portion 106 of the
apparatus housing. As the fluid flows into the bellows reservoir, the bellows will
be expanded from a collapsed into an expanded configuration such as shown in figure 3. As the bellows member expands it will urge a telescopically movable
volume indicator member 176 that is carried within a second portion 108 of the
housing and in engagement with the stored energy source, or spring member 120
causing it to compress. As the reservoir 112 fills with fluid from the filling syringe,
any gases trapped within the reservoir will be vented to atmosphere via vent means
"V" mounted in control knob assembly 160. A seal ring 113 (figure 3), prevents
leakage of fluid between bellows 110 and portion 106 of the housing.
With the infusion apparatus interconnected with the patient's clothing by
means of a spring clip assembly 184, which is affixed to the side of the device
housing in the manner shown in figures 2 and 5, and with the administration set
148 interconnected with the patient, opening the fluid delivery path to the
administration set can be accomplished by rotating the control knob from the "off
position to the "on" position. Upon opening the fluid delivery path, the stored
energy means, or spring member 120, will tend to return to its precompressed or
less compressed starting configuration thereby controllably urging fluid flow
outwardly of reservoir 112 via the flow rate control means of the invention,
passageway 168 of the control knob assembly and delivery passageway 152
formed in housing portion 106. As the fluid flows outwardly of the apparatus due
to the urging of the stored energy means, the bellows structure 110 will be
collapsed and at the same time member 176 will travel inwardly of housing portion 108. Coupling member 176, which forms a part of the volume indicator means of
the invention, includes a radially outwardly extending indicating finger 176a that is
visible through a volume indicator window 177 that is provided in a second portion
108 of the apparatus housing and also comprises a part of the volume indicator
means of the invention (Fig. 1 and 2). Indicia 179, which are provided on indicator
window 177, function to readily indicate to the caregiver the amount of fluid
remaining within bellows fluid reservoir 112. Housing portion 106 includes an
inwardly extending ullage portion 180 that functions to ensure that substantially all
of the medicinal fluid contained within the bellows reservoir will be expelled
therefrom.
As previously discussed, a number of beneficial agents can be introduced
into reservoir 112 and can be controllably dispensed to the patient including, by
way of example, medicaments of various types, drugs, pharmaceuticals, hormones,
antibodies, biologically active materials, elements, chemical compounds, or any
other suitable material useful in diagnostic cure, medication, treatment or
preventing of diseases or the maintenance of the good health of the patient.
Referring next to figure 17, an alternate form of flow control means of the
invention is there shown. This flow control means can be mounted within housing
104 in place of flow control assembly 130 and functions to precisely control the
rate of fluid flow from reservoir 112 toward the patient. In the form of the invention shown in figure 17, the flow control means comprises a flow control
assembly generally designated in the drawings by the numeral 180. Flow control
assembly 180 here comprises a first component or inlet manifold 180a having an
inlet port 183 that can be placed in communication with the outlet 116 of the fluid
reservoir 112 and an outlet manifold 180b that can be interconnected with first
component 180a by means of a pair of separator plates or components 181 and
182. Outlet manifold component 180b has an outlet port 181 that is in
communication with the outlet 182a of separator plate 182 and also in
communication with the outlet of the apparatus. Intake manifold 180a has an inner
surface that is provided with a plurality of interconnected imbedded capillaries
184. Capillaries 184 have input and output channels 184a that are in
communication both with inlet port 183 and with an outlet port 185 formed in the
inlet manifold. These input and output channels are typically substantially larger
than the intermediate rate control channels. Disposed adjacent manifold 180a is
separator plate 181. Separator plate 181 has an inner surface that is also provided
with a plurality of imbedded capillaries 186 that also have larger input and output
channels 186a that are in communication with outlet port 185 formed in the inlet
manifold. Fluid flowing from capillaries 184 flows into capillaries 186 via an inlet
port 181a and then outwardly of separator plate 181 via an outlet port 181b. Separator plate 182, which is disposed intermediate separator plate 181 and
outlet manifold 180b, has an inner surface that is provided with a plurality of
interconnected capillaries 187 that receive the fluid flowing outwardly of outlet
port 181b. After the fluid flow through capillaries 187, it will flow toward outlet
181 of outlet manifold 180b via outlet port 182a. Capillaries 187 also have larger
input and output channels 187a. The various components that make up the flow
control assembly are preferably adhesively bonded together. It is to be noted that
the rear surfaces of the plates are planar and cooperate with the capillaries to form
fluid flow passageways.
By controlling the length and depth of capillaries 184, 186, and 187, the rate
of fluid flow flowing outwardly of outlet 181 can be precisely controlled. In this
regard, it is to be understood that the capillaries of the flow control assembly can
take several forms and be of various sizes depending upon the end use of the fluid
delivery device.
Thermal bonding may be performed by using a channeled plate and an
adjacent planar surface plate that are of similar polymeric materials. In this case
the two plates are placed in contact with one another confined mechanically and
heated 2-5°C above their glass transition temperatures. Following a holding period
sufficient enough for the polymer molecules of the two surface interpenetrate with
one another, the temperature is slowly reduced and a stress free bonded interface with imbedded microchannels is yielded. The bonding material or adhesive may
be of the theπno-melting variety or of the liquid or light curable variety for
thermo-melting adhesives, the adhesive material is melted into the two opposed
surfaces, thereby interpenetrating these surfaces and creating a sealed channel
structure.
Liquid curable bonding materials or adhesives and light curable bonding
materials or adhesives may be applied to one of the surfaces of one of the plates.
Subsequently, the other surface is brought into contact with the coated surface and
the adhesive is cured by air exposure or via irradiation with a light source. Liquid
curable bonding materials or adhesives may be elastomeric (e.g. thermoplastic
elastomers, natural or synthetic rubbers, polyurethanes and silicones). Elastomeric
bonding materials may or may not require pressure to seal the channel system.
They may also provide closure and sealing to small irregularities in the opposed
surface of the channel system.
A channel system may be formed and sealed in cases where two surfaces are
being joined and one of the surfaces has one or more apertures. In order to
promote bonding between these two surfaces, a vacuum may be applied to the
apertures. Bonding may then be accomplished by thermal methods or after
previously having applied a bonding material or adhesive. Reference should also be made to U. S. Patent Numbers 6,182,733;
6,555,067; 6,425,972; 5,882,465; 4,999,069; and 5,376,252 which describe various
bonding techniques. Reference should also be made to Publication No.
W099/56954 and WO94/29400. It should also be understood that alternate
bonding techniques such as sonic welding and laser thermal bonding techniques
can be used.
Turning now to figure 18, still another form of flow control means of the
invention is there shown. This flow control means can also be mounted within
housing 104 in place of flow control assembly 130 and functions to precisely
control the rate of fluid flow from reservoir 112 toward the patient. In the form of
the invention shown in figure 18, the flow control means comprises a bonded-flow,
laminate-stack control assembly generally designated in the drawings by the
numeral 190. Flow control assembly 190 here comprises a first component or inlet
manifold 190a having an inlet port 191 that can be placed in communication with
the outlet 116 of the fluid reservoir 112 (figure 3) and a second component or
outlet manifold 190b that can be interconnected with intake manifold 190a by
means of a separator component or plates 192 and 193. Outlet manifold 190b has
an outlet port 194 that is in communication with the outlet 195a of separator plate
193 and also in communication with the outlet of the apparatus. Intake manifold
190a has an inner surface that is provided with a plurality of interconnected imbedded capillaries 196. Capillaries 196 are in communication both with inlet
port 191 and with an outlet port 197 formed in the inlet manifold. Disposed
adjacent manifold 190a is the separator plate 192. Separator plate 192 has an inner
surface that is provided with a plurality of imbedded capillaries 198 that are in
communication with outlet port 197 formed in the inlet manifold. Fluid flowing
from capillaries 196 flows into capillaries 198 via an inlet port 197 and then
outwardly of separator plate 192 via an outlet port 200.
Separator plate 195, which is disposed intermediate separator plate 192 and
outlet manifold 190b, has an inner surface that is provided with a plurality of
interconnected capillaries 201 that receive the fluid flowing outwardly of outlet
port 200. After the fluid flows through capillaries 201 it will flow toward outlet
194 of outlet manifold 190b via an outlet port 195a.
As before, by controlling the length, depth and width of capillaries 196, 198
and 201, the rate of fluid flow flowing outwardly of outlet 194 can be precisely
controlled. It is to be noted that the rear surfaces of the plates are planar and
cooperate with the capillaries to form fluid flow passageways.
Referring next to figures 19 and 19A, yet another form of flow control
means of the invention is there shown. This flow control means can also be
mounted within housing 104 in place of flow control assembly 130 and functions
to precisely control the rate of fluid flow from reservoir 112 toward the patient. In the form of the invention shown in figures 19 and 19A, the flow control means
comprises a flow control assembly generally designated in the drawings by the
numeral 200. Flow control assembly 200 here comprises a first component or inlet
manifold 202 having an inlet port 202a that can be placed in communication with
the outlet 116 of the fluid reservoir 112 and a second component or outlet manifold
204 that can be interconnected with intake manifold 202 by means of a separator
component or plate 206. Outlet manifold 204 has an outlet port 204a that is in
communication with the outlet 206a of separator plate 206 and also in
communication with the outlet of the apparatus. Separator plate 206 has first and
second opposing surfaces 208 and 210, each of which is provided with a plurality
of interconnected, laser-etched capillaries 214. Capillaries 214 are in
communication both with inlet port 202a and with an outlet port 204a formed in
the outlet manifold. As illustrated in figure 19, the inner surfaces of the inlet and
outlet manifold cooperate with the capillaries to form fluid flow channels through
which the medicinal fluid flows.
Referring once again to figures 19B through 19F, the various types of
springs suitable for use as the stored energy source of the invention are there
illustrated and described. By way of background, springs are unlike other
machine/structure components in that they undergo significant deformation when loaded and their compliance enables them to store readily recoverable mechanical
energy.
With respect to the specific spring configurations shown in the drawings, the
following discussion amplifies the descriptive notations in the drawings.
Compression Springs:
Compression springs are open-wound helical springs that exert a load or
force when compressed. They may be conical or taper springs, barrel or convex,
concave or standard cylindrical in shape. Further, they may be wound in constant
or variable pitch. The ends can be closed and ground, closed but unground, open
and unground and supplied in alternate lengths. They also can include a
configuration where a second compression spring of similar or different
performance characteristics which can be installed inside the inside diameter of
their first compression spring, i. e., a spring in a spring.
Many types of materials can be used in the manufacture with compression
springs including: Commercial Wire (BS5216 HS3), Music Stainless Steel,
Phosphur Bronze, Chrome Vanadium, Monel 400, Inconel 600, Inconel X750,
Nimonic 90: Round wire, Square and Rectangular sections are also available.
Exotic metals and their alloys with special properties can also be used for special
and applications; they include such materials as beryllium copper, beryllium
nickel, niobium, tantalum and titanium. Compression springs can also be made from plastic including all
thermoplastic materials used by custom spring winding service providers. Plastic
springs may be used in light-to-medium duty applications for quiet and corrosion-
resistant qualities.
Wave Spring:
Multiwave compression springs, an example of which is shown as "F" in
figure 19C are readily commercially available from sources, such as the Smalley
Company of Lake Zurich, Illinois. As previously discussed, such springs operate
as load-bearing devices. They can take up play and compensate for dimensional
variations within assemblies. A virtually unlimited range of forces can be
produced whereby loads built either gradually or abruptly to reach a predetermined
working height. This establishes a precise spring rate in which load is proportional
to deflection, and can be turned to a particular load requirement.
Typically, a wave spring will occupy an extremely small area for the amount
of work it performs. The use of this product is demanded, but not limited to tight
axial and radial space restraints.
Disc Springs:
Disc springs I, J, K, and L of figures 19C and 19D compare conically shaped
annular discs (some with slotted or fingered configuration) which when loaded in the axial direction, change shape. In comparison to other types of springs, disc
springs product small spring deflections under high loads.
Some examples of the disc-shaped compression springs include a single or
multiple stacked Belleville washer configuration as shown in G and H of figure
19C, and depending on the requirements of the design (flow rate over time
including bolus opportunity) one or more disc springs can be used and also of
alternate individual thicknesses. Alternate embodiments of the basic disc spring
design in a stacked assembly can be also utilized including specialty disc springs
similar to the Belleville configuration called K disc springs manufactured by Adolf
Schnorr GM8H of Singelfingen, Germany, as well as others manufactured by
Christian Bauer GMBH of Welzheim, Germany.
Disc springs combine high energy storage capacity with low space
requirement and uniform annular loading. They can provide linear or nonlinear
spring loadings with their unique ability to combine high or low forces with either
high or low deflection rates. They can be preloaded and under partial compression
in the design application.
All these attributes, and more, come from single-component assemblies
whose nontangle features (when compared to wirewound, compression springs)
make them ideal for automatic assembly procedures. With respect to the various springs discussed in the preceding paragraphs, it
is to be understood that many alternate materials can be used in the design and
application of disc springs and include carbon steel, chrome vanadium steel,
stainless steel, heat resistant steels, and other special alloys such as nimonic,
inconel, and beryllium copper. In some special applications, plastic disc springs
designs can be used.
It should be further observed that, in comparison to other types of springs,
disc springs produce small spring deflections under high loads. The ability to
assemble disc springs into disc spring stacks overcomes this particular limitation.
When disc springs are arranged in parallel (or nested), the load increases
proportionate to the number of springs in parallel, while when disc springs are
arranges in series (alternately) the travel will increase in proportion to the number
of springs serially arranged. These assembly methods may be combined in use.
One special feature of the disc spring is, undoubtedly, the fact that the
load/deflection characteristic curve can be designed to produce a wide variety of
possibilities. In addition to practically linear load/deflection characteristic curves,
regressive characteristics can be achieved and even disc springs which exhibit
increasing spring deflection while the corresponding disc spring load is decreasing
are readily available. Slotted disc springs present a completely different case. Slotting changes
the load/deflection characteristic of the single disc spring, providing larger spring
deflections for greatly reduced loads. The slotted part is actually functioning as a
series of miniature cantilever arms. In some cases the stacked, slotted disc spring,
as shown in the clover dome design, will also produce a non-linear, stress strain
curve with a noticed flat region (force/deflection). Application and use of this type
of spring operating in this region will provide a near constant force between 15%
and 75% of compression.
As before, by controlling the length and depth and width of capillaries 14,
the rate of fluid flow flowing outwardly of outlet 204a can be precisely controlled.
Turning next to figures 20 through 45, an alternate embodiment of the
infusion device of the present invention is there illustrated and generally
designated by the numeral 221. As best seen in figures 21 A and 2 IB, the
apparatus here comprises an outer housing 222 having first, second and third
portions 222a, 222b and 222c respectively. Disposed within outer housing 222 is
an inner, expandable housing 223 having a fluid reservoir 224 (figure 22) provided
with an inlet 224a (figure 22) for permitting fluid flow into the fluid reservoir and
an outlet 224b for permitting fluid flow from the fluid reservoir. Expandable
housing 223, which can be constructed from a metal or plastic material and can
include a coating of the character previously described, comprises a bellows structure having an expandable and compressible, accordion-like, generally
annular-shaped sidewall 223a, the configuration of which is best seen in figures
21 A and 2 IB. It is to be understood that the bellows can be constructed in various
configurations and, for example, can also be generally rectangular in cross_section.
Disposed within second portion 222b of outer housing 222 is the novel
stored energy means of the invention for acting upon inner expandable housing
223 in a manner to cause the fluid contained within fluid reservoir 224 to
controllably flow outwardly of the housing. In the present form of the invention,
this important stored energy means comprises a compressively deformable, spring
member 225 that is carried within the second portion 222b of the outer housing. In
a manner presently to be described spring member 225 is further compressed from
its initial state by fluid flowing into reservoir 224 and then is controllably
expanded to cause fluid flow from the outer housing through the dispensing means
of the invention. Stored energy member 225 can be constructed from a wide
variety of materials including spring steel and plastic.
Forming an important aspect of the apparatus of this latest form of the
invention is fill means carried by the third portion 222c of outer housing 222 for
filling the reservoir 224 with the fluid to be dispensed. As best seen in figure 21 A,
third portion 222c includes a fluid passageway 226 in communication with inlet
224a of fluid reservoir 224. Proximate its lower end 226a, fluid passageway 226 communicates with a cavity 227 formed within the third portion 222c of the
housing. Disposed within cavity 227 is an elastomeric pierceable septum 228 that
comprises a part of one form of the fill means of this latest form of the invention.
Septum 228 can be bonded in place and is held in position by a retainer 228a and is
pierceable by the needle of the syringe which contains the medicinal fluid to be
dispensed and which can be used in a conventional manner to fill or partially fill
reservoir 224 via passageway 226. Septum 228 can comprise a conventional or a
slip filling septum. Additionally, septum 228 can be replaced with a needleless
check valve with luer attachments.
Third portion 222c of housing 222 also includes a first chamber 230 for
telescopically receiving a first medicament containing fill vial 232 and a second
chamber 234 for telescopically receiving a second medicament containing vial 236.
An elongated support 238 is mounted within first chamber 230 and a second
elongated support 240 is mounted within second chamber 234. Each of the
elongated supports 238 and 240 has an integrally threaded end portion 241 and
carries a longitudinally extending, elongated hollow needle 242. Each of the
hollow needles 242 has a flow passageway 242a that communicates with fluid
passageway 226. First chamber 230, second chamber 234, elongated support 238,
elongated support 240 and hollow needles 242 together comprise an alternate form of the fill means of the apparatus of the invention. The method of operation of this
alternate form of fill means will presently be described.
Forming another very important aspect of the apparatus of the present
invention is a novel flow control means that is connected to first portion 222a of
outer housing 222. This flow control means functions to precisely control the rate
of fluid flow outwardly from reservoir 224 and toward the patient. In the form of
the invention shown in figures 20 through 45 the flow control means comprises a
flow control assembly generally designated in the drawings by the numeral 246.
This novel flow control assembly here comprises an ullage defining member 248
having a first portion 248a disposed within inner, expandable housing 223 and a
second portion 248b that extends outwardly from housing 222 in the manner
shown in figure 21 A. For a purpose presently to be described, member 248b has a
fluid passageway 249 that is in communication with an outlet of the flow control
subassembly 250, the character of which will next be described.
Referring to figures 35 through 45, it can be seen that flow control
subassembly 250, which comprises a part of flow control assembly 256, comprises
an outer casing 252 having a plurality of circumferentially spaced-apart fluid
outlets 254, a flow control member 256 telescopically receivable within casing 252
and a selector knob 258 that is interconnected with control member 256 in the
manner shown in figures 38 and 39. An elastomeric sealing band 253, which has the unique configuration shown in figures 2 IF and 2 IE, prevents leakage between
casing 252 and member 248. As best seen in figures 36 and 39, flow control
member 256 is uniquely provided with a plurality of elongated flow control
channels 260, each having an inlet 260a and an outlet 260b. The flow channels
260 may be of different sizes, lengths and widths and in alternate configurations as
shown by figures 40 and 40 A which depict alternate forms of the flow control
member. The flow control member shown in figure 40 is identified as 258a, while
the flow control member shown in figure 40A is identified as 258b. Flow control
member 258b is provided with flow channels 250b that are formed in spaced-apart
flow segments 251, each of which has a circuitous microfluidic flow path or micro
channel of the configuration shown in figure 40 A. Further, the flow control
channels may be rectangular in cross-section as illustrated in Fig. 37, or
alternatively, they can be semicircular in cross-section, U-shaped in cross-section,
or they may have any other cross-sectional configuration that may be appropriate
to achieve the desired fluid flow characteristics. When the flow control member is
properly positioned within outer casing 252, the inner surface of the outer casing
wall cooperates with channels 260 to form a plurality of generally spiral-shaped
fluid flow passageways each being of different overall length and flow capacity.
When the flow control member is positioned within the outer casing, a notch 256b
formed in member 256 receives a tongue 252a provided on casing 252 so as to precisely align the outlets 260b of the flow channels 260 with fluid outlets 254
formed in casing 252. The various components of the flow control assembly are
appropriately bonded, or otherwise sealably interconnected.
The flow control channels 260 can be made by several techniques including
(micro) injection molding, injection-compression molding, hot-embossing and
casting. The techniques used to make these imbedded fluid channels are now
common-place in the field of microfluidics, which gave rise to the lab-on-a-chip,
bio-MEMS and micro-total analysis systems (m-TAS) industries. Additionally,
depending on the size of the fluid channels required for a given flow rate, more
conventional injection molding techniques can be used.
The first step in making the channels using an injection molding or
embossing process is a lithographic step, which allows a precise pattern of
channels to be printed on a "master" with lateral structure sizes down to 0.05 mm.
subsequently, electroforming is performed to produce the negative metal form, or
mold insert. Alternatively for larger channel systems, precision milling can be used
to make the mold insert directly. Typical materials for the mold insert or
embossing tool are Nickel, Nickel alloys, steel and brass. Once the mold insert of
embossing tool is fabricated, the polymer of choice may be injection molded or
embossed to yield the desired part with imprinted channels. Alternatively, channels can also be made by one of a variety of casting
processes, In general, a liquid plastic resin (e.g. a photopolymer) can be applied to
the surface of a metal master (made by the techniques described above) and then
cured via thermal of UV means. After hardening, the material is then "released"
from the mold to yield the desired part. Additionally, there are similar techniques
available that utilize CAD data (of the desired channel configuration) and direct
laser curing of a liquid monomer to yield a polymerized and solidified part with
imbedded channels. This process is available by contract, for example, for
MicroTEC MbH of Duisburg, Germany.
A number of materials can be used to fabricate flow control member 256.
While medical grade polymers are the most appropriate materials, other materials
can be used including: Thermoplastics (embossing & injection molding);
Duroplastics (injection molding); Elastomers (injection compression molding and
soft lithography); Polyurethanes (castings); and Acrylics and Epoxies (RMPDO
from microTEC). Additionally, the flow control members 256 can be constructed
from various metals, metal alloys, silicon, silicon dioxide and inorganic oxides.
Selector knob 258, which comprises a part of the selector means of the
invention, is rotatably connected to second portion 248b of ullage defining member
248 and, in a manner presently to be described, functions to rotate the assembly
made up of outer casing 252 and flow control member 256. In this way, a selected outlet 254 in casing 252 can be selectively aligned with flow passageway 249
provided in the ullage defining member (see figures 21 A and 2 IB).
Turning once again to figure 20, also forming a part of the fluid dispensing
apparatus of the present invention is dispensing means for dispensing fluid to the
patient. In the present form of the invention this dispensing means comprises an
administration set 264 that is connected to the first portion 222a of housing 222 in
the manner shown in the drawings. The flow channel in the proximal end 265a of
administration line 265 of the administration set 264 is in communication with
fluid passageway 249 in the manner best seen in figure 21 A. Disposed between
the proximal end 265a and the distal end 265b of the administration line is a
conventional gas vent and particulate filter 266. Provided at the distal end 265b is
a luer connector 268 and cap 286a of conventional construction.
Turning now to figures 23 and 24, the details of construction of the vial
means or shell vial 270 is there shown. As indicated in these figures, each of the
glass or plastic vial housings has a fluid chamber 272 for containing an injectable
fluid. Chamber 272 is provided with a first open end 270a and second closed end
270b. First open end 270a is sealably closed by closure means here provided in the
form of an externally threaded, elastomeric plunger 274 which is telescopically
movable within the vial from a first location shown in figure 23, where the plunger is disposed proximate first open end 270a, to a second device-fill location where
the plunger is disposed proximate second closed end 270b.
After removal of the closure 273, which forms a part of the third portion
222c of housing 222 (figure 22), vials 232 and 236 can be inserted into chambers
230 and 234 respectively. As the fill vials are so introduced and the plungers 274
are threadably interconnected with ends 241 of supports 238 and 240, the sharp
ends of the elongated needles 242 will pierce the central walls 274a of the
elastomeric plungers. Continuous pushing movement of the vials into chambers
230 and 234 will cause the structural supports 238 and 240 to move the elastomeric
plungers inwardly of the vial chambers in a direction toward the second closed end
270b of the vials. As the plunger is moved inwardly of the vial, the fluid contained
within the vial chamber will be expelled therefrom into the hollow elongated
needles 242a. As best seen in figure 21 A, the fluid will then flow past elastomeric,
umbrella type check valves 278 and into passageways 280 formed in third portion
222c of the apparatus housing. Umbrella type check valves 278 function to control
fluid flow from the elongated hollow needles 242 toward fluid passageways 280.
From passageways 280 the fluid will flow into passageway 226 and then into
internal fluid reservoir 224 of the bellows component 223 via ullage filling
microchannels 224a. It is to be understood that the vials 232 and 236 can contain
the same or different medicinal fluids and can be introduced into their respective chambers one at a time as shown in figure 22 or simultaneously as shown in figure
21.
As the fluid flows into the bellows reservoir, the bellows will be expanded
from the collapsed configuration shown in figure 21B into an expanded
configuration, such as shown in figure 22. As the bellows member expands it will
urge a telescopically movable volume indicator or coupling member 282 that is
carried within the second portion of the housing in engagement with the stored
energy source, or spring member 225 causing it to further compress.
It is also to be understood that, if desired, the reservoir of the bellows
component can also be filled by alternate filling means of the character previously
described which comprises a syringe having a needle adapted to pierce the
pierceable septum 228 which is mounted within third portion 222c of the apparatus
housing. As the reservoir 224 fills with fluid either from the fill vials or from the
filling syringe, any gases trapped within the reservoir will be vented to atmosphere
via vent means "V" mounted in portion 248b of the ullage member. This vent
means here comprises a gas vent 283 that can be constructed of a suitable
hydrophobic porous material such as a porous plastic. Gas vent 283 is held in
position within the housing by a bonded retainer ring 283a (figure 21 A).
Upon opening the fluid delivery path to the administration set 264 in a
manner presently be described, the stored energy means, or member 225, will tend to return to its initial starting, less compressed configuration thereby controllably
urging fluid flow outwardly of reservoir 224 via the flow control means of the
invention.
As previously discussed a number of beneficial agents can be contained
within vials 232 and 236 and can be controllably dispensed to the patient
including, by way of example, liquid injectable medicaments of various types,
drugs, pharmaceuticals, hormones, antibodies, biologically active materials,
elements, chemical compounds, or any other suitable material useful in diagnostic
cure, medication, treatment or preventing of diseases or the maintenance of the
good health of the patient.
Considering next the operation of the flow rate control means of the
invention, as the fluid contained within the bellows reservoir 224 is urged
outwardly thereof by the stored energy means, the fluid will flow into a fluid
passageway 284 formed in the first portion 248a of ullage member 248. The fluid
will then flow under pressure through a filter means shown here as a filter 286 that
is peripherally bonded within a cavity provided in the flow control member 256 of
the flow control subassembly 250. Filter 286, which functions to filter particulate
matter from the fluid flowing outwardly from reservoir 224 is of a character well
known to those skilled in the art and can be constructed from various readily
available materials such as polysolfone and polypropylene wafers having a desired porosity. After flowing through filter 286, the fluid will flow, via a stub
passageway 288 (figure 21 A) into the distribution means of the invention for
distributing fluid from the fluid reservoir to each of the plurality of spiral
passageways 260. This distribution means here comprises several radially
outwardly extending flow passageways 290 formed in flow control member 256.
The filtered fluid will fill passageways 290 and then will flow into the plurality of
spiral passageways 260 formed in member 256 via outlets 260b, which
communicate with passageways 260 (see figure 39). The fluid contained within
spiral passageways 260 can flow outwardly of the device via outlets 260b only
when one of the fluid outlets 254 formed in casing 252 is aligned with reservoir
outlet passageway 249 (figure 21 A).
Selection of the passageway 260 from which the fluid is to be dispensed is
accomplished by rotation of the selector knob 258 which, as best seen in figure 39,
includes a reduced diameter portion 258a having a slot 258b formed therein. As
illustrated in figure 36, slot 258b is adapted to receive a spline 256a (figure 36)
formed anteriorly of member 256. With this construction, rotation of selector
member 258 by gripping a transversally extending finger gripping member 258g
will impart rotation to member 256. As seen in figure 39, casing 252 is also
provided with an inwardly extending spline segment 252a that is received within a
slot 256b formed in the rearward periphery of member 256 (figure 38). Accordingly, rotation of member 256 will also impart concomitant rotation to
casing member 252.
As illustrated in figures 35 and 39, selector knob 258 is provided with a
plurality of circumferentially spaced apart indexing cavities 258c that closely
receive an indexing finger 294 which forms a part of the indexing means of the
invention, which means comprises a locking shaft cover 296 that is connected to
third portion 222c of the apparatus housing (see figures 20 and 21 A). Indexing
finger 294 is continuously urged into engagement with a selected one of the
indexing cavities 258c by a coil spring 298 that also forms a part of the indexing
means of the invention. Coil spring 298 can be compressed by an inward force
exerted on an indexing shaft 300 that is mounted in locking shaft cover 296 and is
movable from the extended position shown in figure 21 A to an inward, finger
release position wherein spring 298 is compressed and finger 294 is retracted from
a selected indexing cavity 258c (see also figures 30, 31 and 32). With finger 294
in its retracted position it is apparent that control knob 258 can be freely rotated to
a position wherein flow rate indicia 304 formed on the periphery of knob 258
(figure 35) can be viewed through a viewing window 305 formed in the first
portion 206 of the apparatus housing. Locking means, here provided in the form of
a locking member 310 (see figure 29), is also carried by the locking shaft cover
and, when moved from the release position shown in figure 33 into the locking position shown in figure 34, prevents inward movement of the indexing shaft 300
against the urging of spring 298. A spring biased retainer pin 311 (figure 31)
functions to retain the selector knob in position within housing 222a.
When the selector knob is in the desired position and pressure is released on
indexing shaft 300, spring 298 will urge finger 294 of the indexing means of the
invention into locking engagement with one of the indexing cavities 258c thereby
placing a selected one of the spiral shaped flow control channels 260 in
communication with the fluid reservoir 224 via passageways 290, 288 and 284. As
the fluid flows outwardly of the apparatus due to the urging of the stored energy
means or spring member 225, the bellows structure 223 will be collapsed and at the
same time member 282 will travel inwardly of housing portion 222b. Coupling
member 282, which forms a part of the volume indicator means of the invention,
includes a radially outwardly extending indicating finger 282a that is visible
through a volume indicator window 313 that is provided in a second portion 222b
of the apparatus housing and also comprises a part of the volume indicator means
of the invention (figure 20). Indicia 315, which are provided on indicator window
313, function to readily indicate to the caregiver the amount of fluid remaining
within fluid reservoir 224.
Safety disabling means, shown here as a disabling shaft 318 that is
telescopically movable within a passageway 320 formed within housing portion 222a functions to disable the device (figure 22A, 28A), by occluding the output
passageway 249. More particularly, shaft 318 has a distal end.318a, which, upon
insertion of the shaft, will block fluid flow through passageway 249. A retainer
318b normally holds shaft 318 in the retracted position (see figure 22 A).
Referring now to figures 46 through 52, yet another embodiment of the
dispensing apparatus of the present invention is there illustrated and generally
designated by the numeral 330. This alternate form of the apparatus of the
invention is similar in many respects to that shown in figures 20 through 45 and
like numerals are used in figures 46 through 52 to identify like components. The
primary difference between this latest form of the invention and the invention
shown in figures 20 through 45 resides in the fact that two cartridge fill vials of a
different construction are used to fill the fluid reservoir of the apparatus. As
before, the apparatus of this alternate form of the invention comprises an outer
housing 332 having first, second and third portions 334, 336, and 338 respectively.
Disposed within outer housing 332 is an inner, expandable housing 223 that is of
identical construction and operation to the expandable housing of the embodiment
of the invention shown in figures 21A and 21B. As in the earlier described
embodiment, housing 223 includes a fluid reservoir that is provided with an inlet
224a (figure 47) for permitting fluid flow into the fluid reservoir. As shown in
figure 47, expandable housing 223 comprises a bellows structure having an expandable and compressible, accordion-like side wall 223a, which is suitably
bonded at its open end 223b to member 370b.
Disposed within second portion 336 of outer housing 332 is the stored
energy means of the invention for acting upon inner expandable housing 223 in a
manner to cause the fluid contained within the fluid reservoir to controllably flow
through outlet 376. In this alternate form of the invention, the important stored
energy means is identical in construction and operation to the earlier described
stored energy means and here comprises a compressively deformable, wave spring
member 225 that is carried within the second portion 336 of the outer housing. As
before, in operation member 225 is first more fully compressed by fluid flowing
into the reservoir and then is controllably unloaded or expanded to cause fluid flow
from the reservoir.
As in the last described embodiment of the invention, the apparatus of this
alternate form of the invention comprises fill means carried by the third portion
338 of outer housing 332 for filling the reservoir with the fluid to be dispensed.
This fill means is also similar to the earlier described fill means, save for the fact
that the fill means of this latest embodiment comprises a pair of glass or plastic fill
vials or cartridges 342 which each are of identical construction. As in the earlier
described embodiments, the fill means also includes an alternate fill means that
comprises a pierceable septum 344 that is disposed within a cavity 346 formed in the third portion 338 of outer housing 332. Elastomeric septum 344 is pierceable
by the needle of the syringe which contains the medicinal fluid to be dispensed and
which can be used to fill or partially fill the fluid reservoir via a passageway 348
formed in third portion 338.
As best seen in figure 47, third portion 338 of housing 332 includes a pair of
spaced-apart chambers 350 for telescopically receiving the medicament containing
fill vials 342. As shown in figures 47 and 51 a pair of elongated supports 354 are
mounted within a hollow vial cover 356 that forms a part of the third portion 338
of the housing and removably covers the fill vials in the manner shown in figure
47. Each of the fill vial cartridges 342, is of the generally conventional
pharmaceutical industry construction shown in figures 50 and 50A, and each
comprises a hollow glass or plastic body portion 358 that defines a fluid chamber
360. Each fill vial has an open first end 342a and a second end that is closed by a
pierceable, elastomeric septum 362 that is held in place by a mechanical clamping
ring. Mounted proximate the inboard end of each chamber 350 is a hollow needle
364 which is adapted to pierce septum 362 when the fill vials are inserted into
chambers 350in a manner next to be described.
Disposed within each vial reservoir 360 is a plunger 366 that is moved by a
support 354 of vial cover 356 from a first position proximate end 342a of the vial
to a second position. More particularly, as the vial cover 356 is mated with the apparatus housing, the inboard end of each of the elongated supports 354 engages a
plunger 366 urging the plunger inwardly of the vial chamber 360. As each of the
plungers move inwardly of their respective vial reservoirs, the fluid contained in
the reservoir will be forced through hollow needle 364, passed an umbrella check
valve 368 mounted within third housing portion 338, into a stub passageway 370,
into a passageway and finally into fluid reservoir via inlet 224a. As the fluid flows
into the reservoir, it will more fully compress the stored energy means in the
manner previously described.
The apparatus of this latest form of the invention also includes flow control
means that is quite similar in construction and operation to the flow control means
described in connection with the embodiment of the invention shown in figures 20
through 45. This flow control means is connected to first portion 334 of outer
housing 332 and comprises an ullage defining member 370 having a first portion
37 a disposed within inner, expandable housing 223 and a second portion 370b
having a fluid passageway 372 that is in communication with outlet 376 of the
fluid reservoir.
As before, the flow control means includes a flow control subassembly that
is substantially identical in construction and operation to the earlier described flow
control subassembly 250 and is of the configuration shown in figures 35 through
45 of the drawings. For this reason, the details of the construction and operation of the flow control means of this latest embodiment of the invention will not be here
repeated and reference should be made to the earlier description of the flow control
subassembly 250.
Turning once again to figure 46, also forming a part of the fluid dispensing
apparatus of this latest form of the invention is dispensing means for dispensing
fluid to the patient. This dispensing means is identical in construction and
operation to the previously identified administration set 264 and is connected to the
first portion 334 of housing 332.
Upon opening the fluid delivery path to the administration set 264, the stored
energy means, or member 225, will tend to return to its less compressed starting
configuration thereby controllably urging fluid flow outwardly of the device
reservoir via the flow control means of the invention. As the fluid contained
within the bellows reservoir is urged outwardly thereof by the stored energy
means, the fluid will flow into a fluid passageway 376 formed in the first portion
370a of ullage member 370. The fluid will then flow under pressure through a
filter means shown here as a filter 286 that is identical to that previously described.
After flow through filter 286, the fluid will flow, via a stub passageway 378 (figure
47) into the several radially outwardly extending flow passageways 290 formed in
flow control member 256. The filtered fluid will fill passageways 290 and then
will flow into the plurality of spiral passageways 260 formed in member 256 via outlets 254, which communicate with passageways 260 (see figure 36). The fluid
contained within spiral passageways 260 can flow outwardly to the patient via the
administration line only when one of the fluid outlets 254 formed in casing 252 is
aligned with passageway 372 (figure 47).
Selection of the passageway 260 from which the fluid is to be dispensed is
accomplished by rotation of the selector knob 258 in the manner previously
described in connection with the embodiment shown in figures 20 through 45. The
construction and operation of the selector knob, the indexing means and the
locking means is identical to that previously described and will not be redescribed
at this time.
As in the earlier described embodiment of the invention, as the fluid flows
outwardly of the apparatus due to the urging of the stored energy means or spring
member 225, the bellows structure 223 will be collapsed and at the same time
coupler member 282 will travel inwardly of housing portion 336 and will provide
an indication of the volume of fluid remaining in the fluid reservoir in the same
manner as earlier described.
This latest embodiment also includes safety disabling means 318, which is
substantially identical in construction and operation to that previously described.
Turning now to figures 53 through 66, still another form of the dispensing
apparatus of the present invention is there illustrated and generally designated by the numeral 380. This alternate form of the apparatus of the invention is similar in
some respects to that shown in figures 46 through 52 and like numerals are used in
figures 53 through 66 to identify like components. The primary difference
between this latest form of the invention and the invention shown in figures 46
through 52 resides in the fact that one of the two fill vials used to fill the fluid
reservoir of the apparatus is of totally different construction. More particularly,
one of the fill vials is specially designed to enable the reconstitution and
intermixing of a contained lypholized drug with a suitable reconstitution agent
prior to the delivery of the mixture to the fluid reservoir of the device. The second
cartridge will typically carry a diluent to add to the first now injectable drug in
residence in the reservoir.
As in the earlier described embodiments, the apparatus of this latest form of
the invention comprises an outer housing 382 having first, second and third
portions 384, 386 and 388 respectively. Disposed within outer housing 382 is an
inner, expandable housing 223 that is of identical construction and operation to the
expandable housing of the embodiment of the invention shown in figures 46
through 52. As in the earlier described embodiment, housing 382 includes a fluid
reservoir that is provided with an inlet 216 (figure 54) for permitting fluid flow
into the fluid reservoir. As shown in figure 54, expandable housing 223 comprises a bellows structure having an expandable and compressible, accordion like
sidewall 223a.
Disposed within second portion 386 of outer housing 382 is the stored
energy means of the invention for acting upon inner expandable housing 223a in a
manner to cause the fluid contained within the fluid reservoir of the device to
controllably flow through outlet 374. In this latest form of the invention, the
important stored energy means is identical in construction and operation to the
earlier described stored energy means and here comprises a compressively
deformable, spring member 225 that is carried within the second portion 386 of the
outer housing. As before, in operation member 225 is first more fully compressed
by fluid flowing into the device reservoir and then is controllably unloaded or
expanded to cause fluid flow from the reservoir.
As previously mentioned, the apparatus of this latest form of the invention
comprises fill means of a somewhat different construction, that is, carried by the
third portion 388 of outer housing 382 for filling the device reservoir with the fluid
to be dispensed. This fill means, like the last described fill means, comprises a pair
of fill vials or cartridges, one of which, namely fill vial 342, is of identical
construction and operation to the earlier described fill vial 342. The second fill
vial or cartridge designated by the numeral 392 comprises a container of special
design that uniquely contains a lyophilized drug 394 that is separated from a reconstituting fluid 396 by a barrier stopper 398 (figure 61). Lyophilized drug 394
can, by way of example, comprise an anti-infective, an oncolytics agent, a cardiac
drug or various other types of beneficial agents. Cartridge 392 is telescopically
receivable within a vial housing 400 that is of the configuration shown in figs. 54,
58 and 60. As before, vial housing 400 includes a pair of spaced apart pusher
members 402 and 404 which engage plungers 366 (figure 63) and 406 (figure 61)
respectively to push the plungers forwardly of their respective container
reservoirs.
Considering in more detail the novel cartridge assembly 392, as best seen in
figure 61, this cartridge assembly includes a vial 408 that is sealed at one end by a
plunger 406 and at the other end by a pierceable septum 410 (figure 61) that is held
in place by a suitable crimp ring. Formed intermediate the ends of vial 408 is a
raised outer wall portion 408a which permits fluid 396 to bypass elastomeric
barrier stopper 398 as the barrier stopper is urged inwardly of the container by
pressure exerted thereon by the fluid 396. Fluid 396 exerts pressure on barrier
member 398 as a result of pusher member 404 exerting inward pressure on plunger
406, which pressure is, in turn, caused by the inward movement of plunger 406 as
the vial housing is mated with and advanced within the apparatus housing 382.
A continued inward pressure exerted on plunger 406 will cause fluid 396 to
flow past barrier member 398 via wall portion 408a so as to reconstitute lyophilized drug 394 with an internally contained reconstitution agent 396. Further
pressure exerted on plunger 406 will cause the reconstituted drug formed by the
fluid 396 which has been intermixed with drug 394 to flow through a hollow
cannula 412, past check valve 414, into a stub passageway 416 and then into a
passageway 418 and finally into the device reservoir via ullage microchannels 420.
As previously mentioned, plunger 406 is disposed within vial 392 and is
moved by a support 404 of vial closure 400 as the vial cover is mated with the
apparatus housing. As plunger 366 is moved inwardly of vial reservoir 360, the
fluid contained in the reservoir will be forced through hollow needle 412a, passed
an umbrella check valve 414a mounted within third housing portion 388, into a
stub passageway 416, into a passageway 418 and finally into the device reservoir
via ullage reservoir filling channel 420. As the fluid flows into the device
reservoir, it will more fully compress the stored energy means in the manner
previously described.
As in the earlier described embodiments, the fill means also includes an
alternate fill means that comprises a mechanical check valve (not shown) or an
elastomeric pierceable septum 344 that is disposed within a cavity 346 formed in
the third portion 388 of outer housing 382. Septum 344 is pierceable by the needle
of the syringe which contains the medicinal fluid to be dispensed and which can be used to fill or partially fill the device reservoir via passageway 418 formed in third
portion 388.
The apparatus of this latest form of the invention also includes flow control
means that is identical in construction and operation to the flow control means
described in connection with the embodiment of the invention shown in figures 36
through 45. This flow control means is connected to first portion 384 of outer
housing 382 and comprises an ullage defining member 370 having a first portion
370a disposed within inner, expandable housing 223 with which the bellows
slidably cooperates and a second portion 370b having a fluid passageway 372 that
is in communication with outlet 374 of the device reservoir. Once again, the ullage
defining member functions to ensure that substantially all of the medicament is
dispensed from the fluid reservoir.
As before, the flow control means includes a flow control subassembly that
is substantially identical in construction and operation to the earlier described flow
control subassembly 250 and is of the configuration shown in figures 36 and 38 of
the drawings. For this reason, the details of the construction and operation of the
control means of this latest embodiment of the invention will not be here repeated
and reference should be made to the earlier description of the flow control
subassembly 250. Turning once again to figure 53, also forming a part of the fluid dispensing
apparatus of this latest form of the invention is dispensing means for dispensing
fluid to the patient. This dispensing means is identical in construction and
operation to the previously identified administration set 264 and is connected to the
first portion 384 of housing 382.
Upon opening the fluid delivery path to the administration set 264 in the
manner previously described, the stored energy means, or member 225, will tend to
return to its less compressed starting configuration thereby controllably urging
fluid flow outwardly of the device reservoir via the flow control means of the
invention. As the fluid contained within the reservoir is urged outwardly thereof
by the stored energy means, the fluid will flow into a fluid passageway 374 formed
in the first portion 370a of ullage member 370 (figure 54). The fluid will then flow
under pressure through a filter means shown here as a filter 286 that is identical to
that previously described. After flowing through filter 286, the fluid will flow, via
a stub passageway 288 (figure 54) into the several radially outwardly extending
flow passageways 290 formed in flow control member 256 (figure 44). The filtered
fluid will fill passageways 290 and then will flow into the plurality of spiral
passageways 260 formed in member 256 via outlets 260b, which communicate
with passageways 260 (see figure 36). The fluid contained within spiral passageways 260 can flow outwardly of the device only when one of the fluid
outlets 254 formed in casing 252 is aligned with passageway 372 (figure 54).
Selection of the passageway 260 from which the fluid is to be dispensed is
accomplished by rotation of the selector knob 258 in the manner previously
discussed in connection with the earlier described embodiments. The construction
and operation of the selector knob, the indexing means and the locking means is
identical to that previously described and will not be redescribed at this time.
As in the earlier described embodiments of the invention, as the fluid flows
outwardly toward the patient via the administration set 264 due to the urging of the
stored energy means or spring member 225, the bellows structure 223 will be
generally collapsed and at the same time member 282 will travel inwardly of
housing portion 386 and will provide an indication of the volume of fluid
remaining in the fluid reservoir in the same manner as earlier described.
This latest embodiment also includes safety defeat disabling means 318,
which is substantially identical in construction and operation to that previously
described.
Considering next the alternate form of fill cartridge assembly 422, shown in
figure 65. This fill cartridge is similar in some respects to fill cartridge 392 and
includes a vial 424 that is sealed at one end by a plunger 425 and at the other end
by an elastomeric pierceable septum 428. Formed intermediate the ends of vial 424 is a plurality of internal fluid flow passageways 430 which permit fluid 432 to
bypass a strategically position barrier stopper 434 as the barrier stopper is urged
inwardly of the container by pressure exerted thereon by fluid 432. Fluid 432
exerts pressure on barrier member 434 as a result of pusher member 404 of the vial
housing 400 exerting inward pressure on plunger 425, which pressure is, in turn,
caused by the inward movement of plunger 434 as vial housing 400 is mated with
the housing 382 as is advanced therewithin.
A continued inward pressure exerted on plunger 425 will cause fluid 432 to
flow past elastomeric barrier member 434 via internal bypass flow channels 430 so
as to reconstitute lyophilized drug 433 (figure 65). Further pressure exerted on
plunger 425 will advance plunger 434 to a more and subsequently fully distal
location which will cause the reconstituted drug formed by the fluid 432 which has
been intermixed with drug 433 to flow through a hollow cannula 412 past
elastomeric check valve 414, into a stub passageway 416 and then into a
passageway 418 and finally into the device reservoir via filling channel 420 (figure
54).
Referring now to figures 67 through 97, yet another embodiment of the
dispensing apparatus of the present invention is there illustrated and generally
designated by the numeral 442. This alternate form of the apparatus of the
invention is similar in some respects to the previously described embodiments of
Figure imgf000067_0001
are used in figures 67 through 97 to identify like
components. The primary difference between this latest form of the invention and
those previously discussed concerns the provision of a differently configured
stored energy means and of a differently configured flow rate control means.
Further, the reservoir fill means of this latest form of the invention includes only a
single, cartridge type fill vial.
As best seen in figure 67, the apparatus here comprises an outer housing 442
having first, second and third portions 446, 448 and 449 respectively. Disposed
within outer housing 442 is an inner, expandable housing 450, which is generally
similar in construction and operation to expandable housing 223, which housing
was described in connection with the embodiment of figure 21.
Also disposed within outer housing 442 is the novel stored energy means of
the invention for acting upon inner expandable housing 450 in a manner to cause
the fluid contained within the fluid reservoir thereof to controllably flow
outwardly of the housing (figure 72). In this latest form of the invention, this stored
energy means comprises a plurality of cooperatively associated disk springs 453.
These disk springs, exhibit superior load/deflection curves and are ideally suited
for use in the present application. Springs 453 are readily commercially available
from a number of sources including the Schnorr Co. of Sindelfingen, Germany.
As in the earlier described embodiments of the invention, the present invention includes fill means, which are here carried by the third portion 449 of the
outer housing. As before, the fill means functions to fill the device reservoir that is
defined by bellows member 450 with the fluid to be dispensed. As best seen in
figures 67, 68 and 72 third housing portion 449 includes a fluid passageway 454
that is in communication with the inlet or passageway 456 of fluid reservoir.
Proximate its lower end 454a fluid passageway 454 communicates with a cavity
457 formed within the third portion of the housing. Disposed within cavity 457 is a
pierceable septum 458 that comprises a part of the fill means of this latest form of
the invention. Septum 458 is held in position by a retainer 458a and is pierceable
by the needle of the syringe which contains the medicinal fluid to be dispensed and
which can be used in a conventional manner to fill or partially fill the device
reservoir via passageway 454. As the reservoir fills, and gases trapped within the
reservoir will be vented via vents "V".
The fill means also here comprises a cartridge type fill vial 460 which is of
the construction shown in figure 72. As shown in figure 72, the third portion 449 of
the housing includes a chamber 462 for telescopically receiving cartridge fill vial
460. A hollow needle 464 is mounted within third portion 449 of the device
housing and is located proximate the inboard end of chamber 462. When the
cartridge fill vial 460 is inserted into chamber 462 and pushed forwardly into the
position shown in figure 72, hollow needle 464 will pierce a septum 466 that sealably closes the open end of the cartridge fill vial.
As illustrated in figures 70, 71 and 72, the vial cover 469 of portion 449 of
the device housing includes a pusher member 471 which engages a plunger 474 of
vial 460 when the vial cover is mated with the device housing. Pusher member 471
functions to push the plunger forwardly of container reservoir 476 as the vial cover
469 is moved into the fully mated position shown in figure 72. As plunger 474 is
moved forwardly of reservoir 476, the fluid contained in the vial reservoir will be
forced through hollow needle 464, passed a conventional umbrella check valve 480
that is mounted within third housing portion 449, into a stub passageway 482, into
passageways 454 and 456 and finally into the device reservoir. As the fluid flows
into the device reservoir, it will controllably compress the stored energy means, or
disc springs 453.
Turning particularly to figures 78 through 97, the novel flow control means
of the apparatus of this latest form of the invention is there shown. This important
flow control means functions to precisely control the outwardly rate of fluid flow
from the device reservoir toward the patient. In this latest form of the invention,
the flow control means comprises a flow rate control assembly generally
designated in the drawings by the numeral 484. This flow rate control assembly is
non-rotatably mounted within housing portion 446 and includes an elongated
spline 485 that functions to align the assembly within the outer housing. As best seen m ngures /2 and 81, this novel flow rate control assembly here comprises an
inlet manifold 486 having an inlet port 488 (figure 72) that is in communication
with the outlet 489 of the fluid reservoir and an outlet manifold 490 that is
interconnected with inlet manifold 486 by means of a plurality of interconnected
flow rate control plates 492, 494, 496, 498, 500, 502,504, 506, 508 and 510 (see
also figures 82A and 82B).
As indicated in figures 79, 80 and 85, outlet manifold 490 has a plurality of
circumferentially spaced outlet ports, each of which is in communication with an
outlet port of a selected one of the rate control plates. In a manner presently to be
described, by using the selector means of the apparatus these circumferentially
spaced outlet ports can be selectively brought into communication with outlet
passageway 514 of the apparatus and with the administration line 150 of the
administration set 148 (figure 72).
As best seen by referring to figures 82 A and 82B, each of the flow rate
control plates is provided with an elongated micro channel of a particular
configuration. These micro-flow channels can be formed in various ways known
to those skilled in the art. For example, U. S. Patent No. 6,176,962 issued to Soane
et al. describes methods for constructing micro channel structures for use in micro
fluidic manipulations. Similarly, International Publication W099/5694A1
describes such methods. When the rate control plates are assembled in the manner shown in figures 82A and 82B, it is apparent that the micro channel formed in each
of the rate control plates will cooperate with the adjacent planar surface of the next
adjacent rate control plate to form a fluid flow control channel through which the
fluid flowing into inlet 488 can controllably flow. As indicated in the drawings,
one end of each of the micro channels is in communication with the inlet port 488
of the inlet manifold 486 via a center port 489 and the other end of each of the
micro channels is in communication with a selected one of the circumferentially
spaced outlet ports provided in the outlet manifold 490. More particularly, as can
be seen by referring to figures 82 A, 82B, 83 and 88 of the drawings, outlet 492a of
rate control plate 492 is in communication with outlet 521 of outlet manifold 490;
outiet 494a of rate control plate 494 is in communication with outlet 522 of outlet
manifold 490; outlet 496a of control plate 496 is in communication with outlet 523
of manifold 490; outlet 498a of control plate 498 is in communication with outlet
524 of outlet manifold 490 and outlet 500a of rate control 500 is in communication
with outlet 525 of outlet manifold 490, and outlet 502a of rate control plate 502 is
in communication with outlet 526 of outlet manifold 490. In similar fashion, outlet
504a of rate control plate 504 is in communication with outlet 527 of outlet
manifold 490; outlet 506a of rate control plate 506 is in communication with outlet
528 of manifold 490; outlet 508a of control plate 508 is in communication with
outlet 529 of outlet manifold 490 and outlet 510a of rate control plate 510 is in communication with outlet 530 of outlet manifold 490,
With the construction of the flow control means shown in the drawings, fluid
will flow from the device reservoir into inlet port 488 of inlet manifold 486,
through a filter member 533 (figure 85) and thence into micro channel 534 formed
in plate 492. By controlling the length, width and depth of the micro channel 534,
the rate of fluid flow flowing outwardly of outlet 492a can be precisely controlled.
In a manner presently to be described, the fluid will then flow onwardly toward the
administration set via the flow regulation means of the invention. It is to be
understood that micro channel 534 can take various forms and can be of varying
length, width and depth to precisely control the rate of fluid flow their through.
Fluid flowing through inlet port 488 will also flow into micro channel 536
formed in rate control plate 494. Once again, depending upon the length, width
and depth of micro channel 536, the rate of fluid flowing outwardly of outlet 494a
can be precisely controlled. In similar manner, fluid flowing through inlet port 488
will fill micro channel 538 formed in rate control plate 496, will fill micro channel
540 formed in plate 498, will fill micro channel 542 formed in rate control plate
500, will fill rate control micro channel 544 formed in rate control plate 502, will
fill rate control micro channel 546 formed in rate control plate 504, will fill rate
control micro channel 548 formed in rate control plate 506, will fill flow control
micro channel 550 formed in rate control plate 508 and will fill rate control micro chanrϊel 552 ibrrneα in rate control plate 510. After flowing through the rate
control micro channels formed in the various indexedly aligned rate control plates,
the fluid will flow onwardly toward outlet manifold 490 and will fill each of the
stub passageways 555 formed therein (figure 87). The rate of flow of fluid flowing
outwardly of each of the outlet ports of the various rate control plates will, of
course depend upon the configuration of the individual rate control micro channels
formed in the rate control plates.
As shown in figures 72 and 76, a selector knob 558 which is sealably
rotatably connected to first portion 446 of the outer housing, is provided with a
plurality of circumferentially spaced apart indexing cavities 559. Elastomeric
sealing bands 558c and 558d, which are of the unique configuration shown in
figures 72B and 72D, prevent leakage between the cooperatively mated
components. These indexing cavities closely receive an indexing finger 560,
which forms a part of the indexing means of the invention, which means comprises
a front bezel 562 that is connected to the apparatus housing (see figure 67).
Indexing finger 560 is continuously urged into engagement with a selected one of
the indexing cavities 559 by a coil spring 564 that also forms a part of the indexing
means of the invention. Coil spring 564 can be compressed by an inward force
exerted on an indexing shaft 566 that is movable from an extended position to an
inward, finger release position wherein spring 564 is compressed and finger 560 is retracted from a selecteo mαexing cavity 559. With finger 560 in its retracted
position, it is apparent that control knob 558 can be freely rotated to a position
wherein a gripping member 558a can be aligned with selected flow rate indicia 568
formed on the front bezel 562 of the apparatus housing.
When the selector knob is in the desired position and pressure is released on
indexing shaft 566, spring 564 will urge finger 560 of the indexing means of the
invention into locking engagement with one of the indexing cavities 559 thereby
placing a selected one of flow control channels of a flow rate control plate in
communication with flow passageway 558b of the flow control knob (figure 81).
As the fluid flows outwardly of the apparatus due to the urging of the stored energy
means or spring members 453, the bellows structure 450 will be collapsed and at
the same time and indicator member 569 will travel inwardly of the housing.
Member 569, which forms a part of the volume indicator means of the invention,
includes a radially outwardly extending indicating finger 569a that is visible
through a volume indicator window 570 that is provided in a second portion 448 of
the apparatus housing and also comprises a part of the volume indicator means of
the invention. Indicia 571, which are provided on indicator window 570 (figure
69), function to readily indicate to the caregiver the amount of fluid remaining
within fluid reservoir of the device at any point in time.
Referring to figures 67 and 77, disabling means, shown here as a disabling shaft 574 that is telescopically movable within a passageway formed within
housing portion, functions in the manner previously described to disable the device
(see discussion concerning figure 22 A).
Referring particularly to figure 95, selector knob 558 (see also figures 78
and 81), which comprises a part of the selector means of the invention, is sealably
connected to outlet manifold 490 by means of O-Rings "O" and is rotatable with
respect thereto. As previously mentioned, this novel selector means of the
invention functions to control the flow of fluid from outlet manifold 490 toward
the administration set 150. More particularly, as illustrated in figures 95, 95 A and
95B, selector knob 558 is provided with a circumferentially extending flow
channel 578 which is selectively in communication with passageways 555 of outlet
manifold 490 depending upon the position of the selector knob. As illustrated in
figures 95A and 95B, the rearwardly-extending, generally-cylindrical, reduced-
diameter portion 558d of the control knob, which circumscribes the outlet manifold
490, is provided with a circumferentially extending, elastomeric band 582 which
prevents fluid leakage between the outlet manifold and the flange 558d. Outlet
manifold 490 is also provided with a similarly configured, circumferentially
extending, elastomeric band 584. As indicated in figure 95A, elastomeric band
584 has an opening 584a that is in alignment with fluid outlet passageway 514
formed in the first portion 446 of the outer housing (see also figure 72). Elastomeric band 582 also has an opening 582a which is aligned with a radially
extending flow passageway 578b formed on portion 558d of the control knob,
which, in turn, is in communication with circumferentially extending flow channel
578 (figure 95A). With this construction, when the control knob 558 is rotated to a
position such as that illustrated in figure 95 A, wherein one of the outlets of the
outlet manifold is in alignment with the opening 582a formed in the elastomeric
band 582, fluid can flow from that outlet and into circumferentially extending flow
channel 578. From flow channel 578, the fluid can flow into radially extending,
passageway 578b, through opening 584a and into passageway 514. From
passageway 514, the fluid can flow onwardly into the dispensing means or
administration set 148. The rate at which the fluid flows toward the administration
set depends, of course, upon which rate control plate outlet is in communication
with radial passageway 578b formed in the control knob. By way of example, with
the control knob 558 in the position shown in figure 95A, it is to be observed that
the fluid flowing toward the administration set is flowing from outlet 492 a of rate
control plate 492 and will flow at a rate determined by the configuration of rate
control micro channel 534. (see figures 82 and 96).
Having now described the invention in detail in accordance with the
requirements of the patent statutes, those skilled in this art will have no difficulty
in making changes and modifications in the individual parts or their relative assembly in order to meet specific requirements of conditions. Such changes and
modifications may be made without departing from the scope and spirit of the
invention, as set forth in the following claims.

Claims

I CLAIM:
1. A dispensing apparatus for dispensing fluids to a patient comprising:
(a) an outer housing;
(b) an inner, expandable housing disposed within, said outer housing having a fluid reservoir provided with an inlet for permitting fluid flow into said fluid reservoir and an outlet for permitting fluid flow from said fluid reservoir;
(c) stored energy means disposed within said outer housing for acting upon said inner expandable housing to cause the fluid contained within said fluid reservoir to controllably flow through said outlet, said stored energy means comprising a resiliently deformable member carried within said second portion of said outer housing said, member being longitudinally expandable to cause fluid flow from said fluid reservoir;
(d) fill means carried by said outer housing for filling said reservoir with the fluid to be dispensed;
(e) flow control means connected to said outer housing for controlling fluid flow from said reservoir; and
(f) dispensing means operably associated with said flow control means for dispensing fluid to the patient.
2. The apparatus as defined in claim 1 in which said resiliently
deformable member comprises a yieldably deformable spring.
3. The apparatus as defined in claim 1 in which said inner expandable
housing comprises a bellows structure having an accordion-like side wall movable
from a substantially collapsed configuration to a substantially expanded
configuration by fluid flowing into said fluid reservoir.
4. The apparatus as defined in claim 1 further including flow control
means connected to said outer housing for controlling fluid flow between said
reservoir and said dispensing means, said flow control means comprising a flow
control member rotatable within said reservoir and having a plurality of elongated
flow control channels.
5. The apparatus as defined in claim 1 in which said fill means
comprises a first fill vial receivable within said outer housing.
6. The apparatus as defined in claim 5 in which said outer housing
includes:
(a) a fluid passageway;
(b) a first chamber for telescopically receiving said first fill vial; and (c) an elongated support mounted within said first chamber, said elongated support having an elongated hollow needle, said hollow needle defining a flow passageway in communication with said fluid passageway.
7. The apparatus as defined in claim 6 in which said first fill vial has a
first open end, a closed second end and includes ;
(a) a fluid reservoir disposed between said first and second ends; and
(b) a pierceable plunger disposed within said fluid reservoir for movement between first and second positions,
8. The apparatus as defined in claim 7 in which said fill means
comprises a second fill vial receivable within said outer housing and in which said
outer housing includes:
(a) a second chamber for telescopically receiving said second fill vial; and
(b) an elongated support mounted within said second chamber, said elongated support having an elongated hollow needle, said hollow needle defining a flow passageway in communication with said fluid passageway.
9. The apparatus as defined in claim 8 in which said second fill vial has a
first open end, a closed second end and includes; (a) a fluid reservoir disposed between said first and second ends of
said second fill vial; and
(b) a pierceable plunger disposed within said fluid reservoir of said
second fill vial for movement between first and second positions.
10. A dispensing apparatus for dispensing fluids to a patient comprising:
(a) an outer housing having a first, second and third portions;
(b) an inner, expandable housing disposed within said outer
housing, said inner expandable housing having a fluid reservoir provided
with an inlet for permitting fluid flow into said fluid reservoir;
(c) stored energy means disposed within said second portion of
said outer housing for acting upon said inner expandable housing to cause
the fluid contained within said fluid reservoir to controllably flow outwardly
toward the patient, said stored energy means comprising a compressively
deformable, spring member carried within said second portion of said outer
housing, said spring member being expandable to cause fluid flow from said
fluid reservoir;
(d) fill means carried by said outer housing for filling said reservoir
with the fluid to be dispensed; (e) flow control means connected to said first portion of said outer
housing for controlling fluid flow from said reservoir, said flow control
means comprising a flow control assembly including:
(i) an ullage defining member having a first portion disposed within said inner, expandable housing and a second portion having a fluid passageway in communication with said outlet of said fluid reservoir;
(ii) a flow control member rotatably mounted within said first portion of said ullage defining member, said flow control member having a plurality of elongated flow control channels, each of said plurality of elongated flow control channels having an inlet and an outlet; and
(iii) selector means rotatably connected to said second portion of said ullage defining member for rotating said flow control member to selectively align an outlet of one of said elongated flow control channels with said with fluid passageway in said second portion of said ullage defining member; and
(iv) dispensing means for dispensing fluid to the patient, said dispensing means being connected to said second portion of said ullage defining member, and being in communication with said fluid passageway of said second portion of said ullage defining member.
11. The apparatus as defined in claim 10 in which said flow control
assembly further comprises:
(a) an outer casing circumscribing said flow control member; and
(b) distribution means formed in said flow control member for distributing fluid from said fluid reservoir to each of said plurality of elongated flow control channels.
12. The apparatus as defined in claim 11 , in which said flow control
member is provided with an inlet passageway in communication with said fluid
reservoir and in which said flow control assembly further includes filter means
carried by said flow control member for filtering fluid flowing toward said
distribution means.
13. The apparatus as defined in claim 12 in which said distribution means
comprises a plurality of radially extending flow passageways formed in said flow
control member.
14. The apparatus as defined in claim 12 in which said selector means
comprises a selector knob connected to said flow control member, said selector
knob having finger gripping means for imparting rotation to said selector knob to
align said outlet of a selected one of said elongated flow control channels with said outlet of said fluid passageway in said second portion of said ullage defining
member.
15. The apparatus as defined in claim 12, further including volume
indicator means carried by said outer housing for indicating the volume of fluid
remaining in said fluid reservoir.
1 . The apparatus as defined in claim 12 further including disabling
means carried by said outer housing for preventing fluid flow toward said
dispensing means.
17. The apparatus as defined in claim 12 in which said outer housing
includes a cavity in communication with said inlet of said fluid reservoir and in
which said fill means comprises a pierceable septum disposed within said cavity.
18. The apparatus as defined in claim 17 in which said fill means
comprises a first fill vial receivable within said third portion of said outer housing.
19. The apparatus as defined in claim 18 in which said fill means
comprises a second fill vial receivable within said third portion of said outer
housing.
20. The apparatus as defined in claim 19 in which said third portion of
said outer housing includes:
(a) a fluid passageway in communication with said inlet of said fluid reservoir; (b) a first chamber for telescopically receiving said first fill vial; and
(c) an elongated support mounted within said first chamber, said elongated support having an elongated hollow needle, said hollow needle defining a flow passageway in communication with said fluid passageway;
(d) a second chamber for telescopically receiving said second fill vial; and
(e) an elongated support mounted within said second chamber, said elongated support having an elongated hollow needle, said hollow needle defining a flow passageway in communication with said fluid passageway.
21. The apparatus as defined in claim 20 in which each of said first and
second fill vials has a first open end, a closed second end and each includes;
(a) a fluid reservoir disposed between said first and second ends; and
(b) a pierceable plunger disposed within said fluid reservoir for movement between first and second positions.
22. A dispensing apparatus for dispensing fluids to a patient comprising: (a) an outer housing having a first, second and third portions; (b) an inner, expandable nousing disposed within said outer
housing, said inner expandable housing having a fluid reservoir provided
with an inlet for permitting fluid flow into said fluid reservoir;
(c) stored energy means disposed within said second portion of
said outer housing for acting upon said inner expandable housing to cause
the fluid contained within said fluid reservoir to controllably flow outwardly
toward the patient, said stored energy means comprising a yieldably
deformable spring carried within said second portion of said outer housing,
said yieldably deformable spring being expandable to cause fluid flow from
said fluid reservoir;
(d) fill means carried by said outer housing for filling said reservoir
with the fluid to be dispensed;
(e) flow control means connected to said first portion of said outer
housing for controlling fluid flow from said reservoir, said flow control
means comprising a flow control assembly including:
(i) an ullage defining member having a first portion disposed within said inner, expandable housing and a second portion having a fluid passageway in communication with said outlet of said fluid reservoir; (ii) a flow control member rotatably mounted within said
first portion of said ullage defining member, said flow control
member having a plurality of elongated flow control channels, each of
said plurality of elongated flow control channels having an inlet and
an outlet;
(iii) an outer casing circumscribing said flow control member;
(iv) distribution means formed in said flow control member
for distributing fluid from said fluid reservoir to each of said plurality
of elongated flow control channels, said distribution means
comprising a plurality of radially extending flow passageways formed
in said flow control member;
(v) selector means rotatably connected to said second portion
of said ullage defining member for rotating said flow control member
to selective align an outlet of one of said elongated flow control
channels with said fluid passageway of said second portion of said
ullage defining member said selector means comprising a selector
knob connected to said flow control member, said selector knob
having finger gripping means for imparting rotation to said selector
knob to align said outlet of a selected one of said elongated flow control channels with said outlet of said fluid passageway in said second portion of said ullage defining member; and
(vi) dispensing means for dispensing fluid to the patient, said dispensing means being connected to said second portion of said ullage defining member, and being in communication with said fluid passageway of said second portion of said ullage defining member; and
(f) volume indicator means for indicating the volume of fluid remaining in said fluid reservoir.
23. The apparatus as defined in claim 22 further including disabling
means carried by said outer housing for preventing fluid flow toward said
dispensing means.
24. The apparatus as defined in claim 22 in which said outer housing
includes a cavity in communication with said inlet of said fluid reservoir and in
which said fill means comprises a pierceable septum disposed within said cavity.
25. The apparatus as defined in claim 22 further including locking means
carried by said outer housing for blocking rotation of said selector knob.
26. The apparatus as defined in claim 22 in which said fill means
comprises a fill vial receivable within said third portion of said outer housing.
27. The apparatus as defined in claim 25 in which said third portion of
said outer housing includes;
(a) a removable vial cover;
(b) a fluid passageway in communication with said inlet of said fluid reservoir;
(c) a chamber for telescopically receiving said fill vial; and
(d) an elongated support mounted within said removable vial cover.
28. The apparatus as defined in claim 27 in which said fill vial has first
and second ends and includes:
(a) a pierceable septum closing one of said first and second ends;
(b) a fluid reservoir disposed between said first and second ends; and
(c) a plunger disposed within said fluid reservoir for movement between first and second positions.
29. A dispensing apparatus for dispensing fluids to a patient comprising:
(a) an outer housing having a first, second and third portions;
(b) an inner, expandable housing disposed within, said outer housing having a fluid reservoir provided with an inlet for permitting fluid flow into said fluid reservoir and an outlet for permitting fluid flow from said fluid reservoir, said inner expandable housing comprising a bellows structure having an accordion-like side wall movable from a substantially collapsed configuration to an expanded configuration by fluid flowing into said fluid reservoir;
(c) stored energy means disposed within said second portion of said outer housing for acting upon said inner expandable housing to cause the fluid contained within said fluid reservoir to controllably flow through said outlet, said stored energy means comprising a compressively deformable, spring member carried within said second portion of said outer housing, said spring member being expandable to cause fluid flow from said fluid reservoir;
(d) fill means carried by said third portion of said outer housing for filling said reservoir with the fluid to be dispensed;
(e) flow control means connected to said first portion of said outer housing for controlling fluid flow from said reservoir; and
(f) dispensing means operably associated with said flow control means for dispensing fluid to the patient.
30. The apparatus as defined in claim 29 in which said flow control means
comprises at least one flow rate control plate each having at least one elongated
flow channel.
31. The apparatus as defined in claim 29 in which said flow control means
comprises a plurality of operably associated flow rate control plates, each having at
least one microflow channel.
32. The apparatus as defined in claim 29 in which said flow control means
comprises a flow rate control plate having a flow channel having a surface coating.
33. The apparatus as defined in claim 29 in which said flow control means
comprises at least one flow rate control plate having a capillary flow channel.
34. The apparatus as defined in claim 29 in which said spring member
comprises a metal spring.
35. The apparatus as defined in claim 29 in which said spring member
comprises a plastic spring.
36. The apparatus as defined in claim 29 in which said spring member
comprises a compression spring.
37. The apparatus as defined in claim 29 in which said spring member
comprises a Belleville Spring washer.
38. The apparatus as defined in claim 29 in which said spring member
comprises a disc spring.
39. The apparatus as defined in claim 29 in which said spring member
comprises a clover spring.
40. The apparatus as defined in claim 29 in which said spring member
comprises a finger spring.
41. The apparatus as defined in claim 29 in which said side wall of said
bellows structure is coated with a drug compatible coating.
42. The apparatus as defined in claim 41 in which said coating on said
side wall of said bellows structure comprises a plasma containing fluorine
molecules.
PCT/US2005/018495 2004-05-26 2005-05-25 Infusion apparatus WO2005118052A2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP05755527A EP1758639A4 (en) 2004-05-26 2005-05-25 Infusion apparatus

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US10/855,425 US7220245B2 (en) 2004-05-26 2004-05-26 Infusion apparatus
US10/855425 2004-05-26

Publications (2)

Publication Number Publication Date
WO2005118052A2 true WO2005118052A2 (en) 2005-12-15
WO2005118052A3 WO2005118052A3 (en) 2006-09-28

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EP (1) EP1758639A4 (en)
WO (1) WO2005118052A2 (en)

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EP1758639A4 (en) 2012-10-31
US20050277882A1 (en) 2005-12-15
US20070225689A1 (en) 2007-09-27
WO2005118052A3 (en) 2006-09-28
US7220245B2 (en) 2007-05-22
EP1758639A2 (en) 2007-03-07

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