Abstract:
The present invention is directed towards a method and apparatus for packaging or containing, handling and managing of a variety of materials or other contents from a variety of sources which encounter use under various dynamic applications, conditions and for a plurality of purposes. The invention more specifically is directed towards one or more containers or packages, suitably fitted or used for the handling or managing of materials or other contents along one or more cycles or chains of use. The one or more packages or other containers described herein is intended for and/or used in one or more interconnections or associations with not only the “initial purpose” filling, transport, storage, dispensing, pouring, using, releasing of sterile or other fluids or material contents, but also used in association with, and for carrying out, the additional delivering and receiving of said fluids or materials, and the receiving and delivering of said fluids or materials via an ingress and egress, by a variety of ways, for a variety of functions and for a plurality of purposes.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application claims the benefit, under 35 U.S.C. 119(e) of U.S. Provisional Patent Application No. 60/346,416, filed Nov. 1, 2001. 
     Subject matter filing history—This patent application is intended to be continuation (s) of Provisional Patent Application (s) No. 60/201,451 to Romano Titled “Universal, Variable Function and Plural Purpose Material (s)/Content (s) Management Method and Apparatus” and non-provisional PCT Patent Application #US01/40668 to Romano Titled “Materials/Contents Management Method and Apparatus”. The instant patent applications consolidated and continues the embodiments, methods and apparatus of the aforementioned Patent Application and literally incorporates by reference the subject matter directly, by combination and subcombination together with the subject matter and embodiments of this Patent Application. “This patent application incorporates by reference provisional patent application Ser. No. 60/346,416.” 
    
    
     FIELD OF THE SUBJECT MATTER 
     This application relates to the field(s) of supply chains and distribution and consumption of sterile/aseptic liquid/fluent materials. This application also relates to the consumption and collection and disposal chain of waste fluent materials. This subject matter also relates to the manufacturing processes and handling systems for fluent materials packaging in the medical field. 
     Summary of the Subject Matter/Embodiments 
     Sterile/Aseptic liquid materials are supplied, consumed and disposed of by a coordinated, manufactured packaging/handling system and structured for connectability as a fluent material disposal packaging/handling system and integrated into/with patient care. The system comprises a supply and disposal chain system and expands “point(s) of consumption(s)” for sterile/aseptic liquid/materials manufacturing and processes. The embodiments of the subject matter disclosed herein comprise interposing passage conduit structures between similar or dissimilar embodiment enclosures of a fluent material handling system. The system also discloses the many applications whereby interposing passage conduit structures between enclosures made from sterile liquid packaging manufacturing processes and other collection and disposal events may have positive impact on the supply and disposal chain associated therewith. The systems enclosure(s) embodiments may be the same enclosure, a different enclosure and the enclosure may function as an origin, source or delivery destination of fluent materials. In this system the patient may function as an origin, source or delivery destination. The passage conduit structures link the delivery of sterile liquid packaging with collection and disposal packaging by interposition there-between, and broaden point of consumption by the interposition there-between and integration with the health care patient. This subject matter also discloses interposing passage conduit structures manufactured and made for the coordinated connectability, coaptibility and interposition between clean/sterile hermetically sealed sterile liquid packaging and other collection like containers and integrates modes of patient care treatment. Supply chain efficiency, and the potential for reducing medical waste, reducing inventory, reducing costs is the innovation of the herein disclosed subject matter/system. The system is a coordinated manufactured system of enclosures and passageway conduit structures, connectable at port structures for the volumetric assessment and/or matching of incoming/distribution of sterile/aseptic liquids with outgoing/disposal materials. The system is intended to address the supply chain. The subject matter/system offers the customer the planning and matching of in and out going fluent materials and the utilization of sterile liquid delivery packaging for collection and disposal of other fluent materials. The system encompasses generally going from clean to dirty, but the subject matter is not limited to that due to reprocessing potential and other circumstances. Points of consumption may be broadened and expansion may be created characterized as going from the supply side to the disposal side by interposing conduit structures there between or, created characterized as going from the disposal side to the supply side by interposing conduit structures there-between, and based on how the system maybe creatively characterized/described. The enclosure/enclosed space of the herein disclosed sterile liquid/aseptic package container embodiments may well be suited for the enclosing/handling of other materials. These enclosures structures, and the passage conduit structures herein disclosed are manufactured with/for conduit structures and coordinated ports structures coordinating the expansion of consumption for coaptability between sterile liquid packaging and broadening consumption to/with other types of packaging and handling of fluent materials. A sterile liquid package of the embodiments disclosed herein have systematized linkability for uses that coordinate the expansion of the points of consumption to supply and disposal and utilized at the creative discretion of the consumer. The goal of the embodiments/innovations disclosed herein are to empower the consumer to have/make creative decisions for supply chain improvements. 
     Volumetric enclosures provides methods and apparatus for teaching, generating and deriving supply chain efficiency methods and improvement potential. Prime manifold enclosures methods and apparatus provide for deriving and generating efficiency by volumetric displacement and volumetric replacement of dissimilar materials and volumetric displacement and volumetric replacement of material having dissimilar origin. Prime manifold enclosures interposed for cooperative coaptation and flow path communication continuity between gradient matrix flow paths for volumetrically displacing and volumetrically replacing dissimilar materials and volumetrically displacing and volumetrically replacing materials of dissimilar origin. The displacement and replacement of materials may occur from and to a sterile liquid package, hermetically sealed and delivered/distributed with a sterility assurance level required for the delivery of sterile/aseptic liquid packaging to the same package connectable for the disposal of a material not delivered in the package as origin. In process flow continuity embodying volumetric displacement and replacement of distinct/different materials of distinct/different origin interposing manifold/enclosures comprising materials having rigid, and or semi-rigid, and or semi-flexible and or flexible construct characteristics are disclosed for ingressing and egressing fluent materials along gradient pressures flow matrix patterns by the occurrence of differential flow pressures. The embodiment enclosures are interposed along the plow pattern matrices and fluent materials impelled/expelled by pressure gradient inducing events. Flow matrix pressure changes impel/expel fluent materials by any plurality of dynamic causes in the singular or plural sense. structured cooperation/coaptability and flow matrix composite coaptation interposes passage conduit structures between prime manifold enclosures and interposes prime manifold enclosures between variant causes of pressure gradient change resulting in fluent materials impelling conferring efficiency advantages along the associated supply chains. Passage conduit structures manufactured and made for cooperative coaptation and connectability and interposed between the sterile fluent materials package and the collection package, the clean and the dirty, the incoming and the outgoing. New Methods for deriving fluent flow matrix patterns interposing prime manifold enclosures between flow gradient pressure differentials are taught. New Apparatus for generating new matrix patterns comprising fluent materials manifolds cooperatively structured for creating integrated composite communication flow matrix pathways are disclosed. New Supply chain efficiency advantage potential(s) are conferred in part by expansion of traditional points of consumption across the sterile/aseptic/clean enclosure line to the dirty/collection/disposal line, and across distinct traditional disciplines of manufacturing and care by the interposition of prime manifold enclosures between distinct disciplines previously uncoordinated and the interposition of passage conduit structures manufactured for the coordination and management of fluent material across the sterile/clean and collection/dirty barriers. 
     For example, in a fluent material handling system, for handling dissimilar fluent materials of dissimilar origin and intended for dissimilar delivery destination said system including a supply chain for barrier enclosures therefore, a method of increasing supply chain efficiency comprises the steps of constructing a prime manifold barrier enclosure with port structures for ingress and egress of dissimilar fluent materials, fitting said port structures with passage conduit structures coapted for connecting said enclosure with fluent materials sources and delivery destinations, and displacing and replacing said dissimilar fluent materials from and to said enclosure and said sources and said enclosure and said delivery destinations, whereby supply chain efficiency is increased by reducing supply costs and quantities of said enclosures. The embodiment of this system wherein said barrier enclosure has a variable cubic/volumetric capacity. The embodiment of the system including the further step of collecting one or more waste fluent materials in said enclosure for disposal thereof. The embodiment of this system including the further step of applying/providing printed and graphic symbols instructions and other indica in text graphics and/or images on the surface or along with said embodiment in teaching creative packaging, conservation re-cycling supply chain efficiency and environmental awareness. The embodiment of this system wherein said displacing and replacing step occurs and or is controlled by application of differential pressure between said barrier enclosure and said sources and said delivery destinations. The embodiment of this system wherein said displacing and replacing step is affected by the force of gravity. The embodiment of this system wherein said barrier enclosure is constructed from rigid material. The embodiment of this system wherein said barrier enclosure is constructed from semi-rigid material. The embodiment of this system wherein said barrier enclosure is constructed from semi-flexible material. The embodiment of this system wherein said barrier enclosure is constructed from flexible material. The embodiment of this system wherein said fluent material handling system is applied to fluent materials in human health care procedures. The embodiment of this system wherein said fluent material handling system is applied to a continuum of care procedures for a health care patient. 
     In another embodiment example in a fluent material handling system for handling dissimilar fluent materials of dissimilar origin and intended for dissimilar delivery destinations said system including supply and disposal chain for said fluent materials and barrier enclosures therefore, a method of increasing supply and disposal chain efficiency potential comprising the steps of, constructing a prime manifold barrier enclosure with a plurality of ports for ingress and egress of dissimilar fluent materials, fitting said port structures with passage conduits coapted for connecting said enclosure with dissimilar sources and delivery destinations for dissimilar fluent materials, displacing and replacing said dissimilar fluent materials from and to said enclosure and said dissimilar sources and delivery destinations, collecting one or more fluent materials in said enclosure, conditioning said enclosure and said waste fluent material for disposal, whereby supply and disposal chain efficiency potential is increased by reducing supply costs and quantities of said enclosures, quantities and costs of disposal of said enclosures and waste fluent materials and environmental impact therefrom. The method of this embodiment wherein said enclosure has variable cubic/volumetric capacity. The method of this embodiment enclosure wherein said displacing and replacing step is controlled by application of differential pressures between said barrier enclosure and said sources and said delivery destinations. The method of this embodiment wherein said displacing or replacing step is effected by the force of gravity. The method of this embodiment wherein said barrier enclosure is constructed from rigid material. The method of this embodiment wherein said barrier enclosure is constructed from semi-rigid material. The embodiment of this enclosure wherein said enclosure is constructed from semi-flexible material. The method of this embodiment wherein said barrier enclosure is constructed from flexible material. The method of this embodiment wherein said fluent material handling system is applied to fluent materials in human health care procedures. The method of this embodiment wherein said fluent materials handling system is applied to a continuum of care procedures for health care patient(s). The method of this embodiment for creating supply and disposal chain efficiency. 
     In another embodiment example a method of handling dissimilar materials of dissimilar origin comprising the steps of constructing a prime manifold enclosure with port structures for ingress and egress of dissimilar fluent materials, fitting said port structures with passage conduit structures coapted for connecting said enclosure with fluent material sources, displacing and replacing said dissimilar fluent materials from and to said enclosure and said sources, whereby supply chain efficiency for said enclosures is increased by reducing supply costs and quantities. A method of this embodiment wherein said barrier enclosure has a variable cubic capacity. A method of this embodiment including the further step of collecting one of more waste fluent materials in said enclosure for disposal thereof. The method of this embodiment including the further step of providing and or applying printed and or graphic symbols, instructions and other indica with, on the surface or provided with said enclosure teaching conservation, recycling supply chain efficiency and environmental awareness. The method of this embodiment wherein said displacing and replacing step is controlled and/or occurs by application of differential pressure between said barrier enclosure and said sources and said delivery destinations. The method of this embodiment wherein displacing and replacing step is controlled by application of differential pressure between said barrier enclosure and said sources and said delivery destinations. The method of this embodiment wherein said displacing and replacing step is effected by the force of gravity. The method of this embodiment wherein said barrier enclosure is constructed from rigid material. The method of this embodiment wherein said barrier enclosure is constructed from semi-rigid material. The method of this embodiment wherein said enclosure is constructed from semi-flexible material. The method of this embodiment wherein said enclosure is constructed from flexible material. The method of this embodiment wherein said fluent material handling system is applied to fluent materials in human health care procedures. The method of this embodiment wherein said fluent material handling system is applied to a continuum of care procedures for health care patient(s). The method of this embodiment for creating supply and disposal chain efficiency. 
     In another embodiment example a method of handling dissimilar fluent material of dissimilar origin intended for dissimilar destinations comprising the steps of constructing a prime manifold barrier enclosure with a plurality of ports for ingress and egress of dissimilar fluent materials, fitting said port structures with passage conduits coapted for connecting said manifold barrier enclosure with dissimilar sources and dissimilar delivery destinations for dissimilar fluent materials, displacing and replacing said dissimilar fluent material from and to said enclosure and said dissimilar sources and delivery destinations, collecting one or more waste fluent materials in said enclosure and conditioning said enclosure and said waste fluent material for disposal, whereby supply and disposal chain efficiency is increased by reducing supply costs and quantities of said enclosures, quantities and costs of disposal of said enclosures and waste fluent materials and environmental impact therefrom. The method of this embodiment wherein said barrier enclosure has a variable cubic/volumetric capacity. The method of this embodiment wherein said displacing and replacing step is controlled/occurs by application of differential pressures between said barrier enclosures and said sources and said delivery destination. The method of this embodiment wherein said displacing and replacing step is effected by the force of gravity. The method of this embodiment wherein said barrier enclosure is constructed from rigid material. The method of this embodiment wherein said barrier enclosure is constructed from semi-rigid material. The method of this embodiment wherein said barrier enclosure is constructed from semi-flexible material. The method of this embodiment wherein said barrier enclosure is constructed from flexible material. The method of this embodiment wherein said fluent material handling system is applied to fluent materials in human health care procedures. The method of this embodiment wherein said fluent material handling system is applied to a continuum of care procedures for a health care patient(s). The method of this embodiment for creating supply and disposal chain efficiency. 
     Another embodiment example comprising a fluent material handling system for dissimilar fluent material of dissimilar origin and intended for dissimilar delivery destinations comprising, a prime manifold barrier enclosure with port structures for the ingress and egress of said dissimilar fluent materials, passage conduit structures operatively associated with said barrier enclosures and coapted for selectively connecting said barrier enclosure with sources of said dissimilar fluent materials and said delivery destinations, and, means for selectively creating material movement between said sources of fluent material and said barrier enclosure and said delivery destinations. The apparatus of this embodiment wherein said fluent material handling system is applied to fluent materials in human health care procedures. The apparatus of this embodiment wherein said fluent material handling system is applied to a continuum of procedures for a health care patient. The apparatus and methods of this embodiment for creating supply and disposal chain efficiency. 
     Another embodiment example in a supply chain for dissimilar fluent material and barrier enclosures therefore, said fluent materials having dissimilar origins and being intended for dissimilar destination, a fluent material handling system comprising a prime manifold barrier enclosure with a plurality of ports fro ingress and egress of dissimilar fluent materials, passage conduit structures operatively associated with said barrier enclosures and copated for selectively connecting said barrier enclosures with sources of said dissimilar fluent material and said delivery destinations and means for selectively creating material movement between said sources of fluent material and said barrier enclosures and said barrier enclosures and said delivery destinations to selectively displace and replace dissimilar fluent materials therebetween, whereby a reduce number of barrier enclosures required to perform a plurality of separate procedures involving dissimilar fluent materials having dissimilar origin to thereby increase supply and disposal chain efficiency of said dissimilar fluent materials and said barrier enclosures. The apparatus of this embodiment wherein said barrier enclosure has a variable cubic/volumetric capacity. The apparatus of this embodiment wherein said displacing and replacing step is controlled by application of differential pressure between said barrier enclosure and said sources and said delivery destination. The apparatus of this embodiment wherein said displacing and replacing step is effected by the force of gravity. The apparatus of this embodiment wherein said barrier enclosure is constructed from rigid material. The apparatus of this embodiment wherein said barrier enclosure is constructed from semi-rigid material. The apparatus of this embodiment wherein said barrier enclosure is constructed from semi-flexible material. The apparatus of this embodiment wherein said barrier enclosure is constructed from semi-flexible material. The apparatus of this embodiment wherein said barrier enclosure is constructed from flexible material. The apparatus of this embodiment wherein said flexible material handling system is applied to fluent materials in human health care procedures. The apparatus of this embodiment wherein said fluent materials handling system is applied to a continuum of care procedures for a health care patient. The apparatus of this embodiment including the further step of applying and providing printed and graphic symbols and instructions and other indica on the surface, unitary therewith, or with said barrier enclosure teaching conservation, recycling, supply chain efficiency and environmental awareness. The method and apparatus of this embodiment for creating supply and disposal chain efficiency. 
     DESCRIPTION OF THE INVENTION 
     Terms used in the disclosure of the invention are defined as follows:
     Egress: an act, or right of going out; to go out.   Orientation: choice or adjustment of associations, connections, or dispositions as they relate to a relative position.   Ingress: to go in.   Plurality: a state of being plural; at least more than one.   Flow: to cause to flow; material movement.   Control: to exercise restraining or directing influence over; an act or fact of controlling; a means
 
or method of controlling.
   Communication: an act or action of imparting or transmitting; access between places.   Supply: an act, process, or an instance of filling a want or need or of providing someone or something. Chain: a series of events in a temporal order usually connected causally.   Consumption: the utilization of economic goods in the satisfaction of wants.   Disposal: an act or process of disposing.   Waste: thrown away or aside as worthless.   Material: of, relating to, or consisting of matter.   Dispense: administer.   Container: one that contains.   Efficiency: the power, characteristic quality, or manner of operation of an efficient cause.   

     The object(s) of the invention . . . 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  shows an embodiment enclosure having port structures, anti-motion strut supports and two different widths. The embodiment may be hermetically sealed as with a sterile liquid package or sealed otherwise for handling fluent materials. 
         FIG. 2  shows and embodiment having port structures with the port structures lined perpendicular to the port structures of  FIG. 1  embodiment. This embodiment barrier enclosure comprises two widths segments and anti motion struts. This embodiment may be hermetically sealed for sterile liquid packaging or sealed otherwise for handling fluent materials. 
         FIG. 3  shows a passage conduit structure having both ends formed for association/coupling with embodiment enclosure port structures, source, origin and/or delivery destination. A portion of the passageway conduit is enlarged and has markings, graduated and incrementally placed or formed unitary therewith along the enlarged portion thereof for the purposes of viewing fluent material rise and measuring the rates of such rise. Simply put this is to function as an inline urimeter, and may be used to measure any types of fluent materials desired for monitoring. The fluent material rise measurement may be effected by clamping/occluding the conduit structure at clamp site B or by the interposition of a mechanical device such as a valve or a stopcock which may be opened and closed at choice for the timing and initiation of metering sequences. This conduit structure is intended to be made of clear transparent materials so material rise may easily be visualized. This conduit structure is intended to measure urine output and may be imposed between enclosure  38  and a urinary drainage catheter. 
         FIG. 4  show a passage conduit structure embodiment having both ends formed for association with port structures and/or a wound drainage catheter, source, origin or delivery destination. A portion of the passage is enlarged in  FIG. 4 . The enlarged portion has incremental marking or graduated measurements formed unitary therewith or applied thereon for visualization of fluent material rise within the conduit structure. The conduit structure is made from a clear transparent materials so as visualization of fluent material rise is made easily. Fundamentally, this conduit structure enlargement may function as an inline urimeter for the measurement and rate of urinary drainage output but not limited to that. Fluid rise measurement may be initiated by occlusion of the conduit structure at clamp site B or interposition of a stopcock or valve between the port structure of the barrier enclosure and the passage conduit structure. 
         FIG. 5  shows an embodiment of a passage conduit structure formed at both ends for connection/coaptation to a port structure and a source, origin or delivery destination. One end may be connected to an enclosure barrier the other end may be connected to a urinary drainage catheter. Said passage conduit structure is show with incremental markings and or graduated markings for the visualization of fluid rise and change of fluid flow output. 
         FIG. 3 ,  FIG. 4 , and  FIG. 5  show embodiments which may be made of clear transparent material so that visualization of fluids/fluent materials is easy and may be considered useful and functional in the metering of urine drainage flow from the bladder. 
         FIG. 6  shows a passage conduit structure formed for connectability to a barrier enclosure for receiving fluent materials from a bladder via a urinary drainage catheter. 
         FIG. 7  show an embodiment of a passage conduit structure having ends formed at one end for connectability to a fluent material barrier enclosure and at the other end for fitting to a wound drain catheter. 
         FIG. 8  shows and embodiment of a passage conduit structure having ends formed for connectability and fitting to port structures, sources, origins an delivery destinations and to a barrier enclosure end and for fitting/refitting to a source, origin or fluent material delivery destination. 
         FIG. 6   a  shows the embodiment of a passage conduit structure with one end formed for connectability and fitting to an intravenous solution barrier enclosure at one end, and for fitting to an intravenous access at the other end. The embodiment depicting the addition to the fluent materials of formularies, anesthetic agents, mixing of pharmaceutical preparations and or drugs being added to the fluent materials at some point along the passage conduit structure and or the barrier enclosure. 
         FIG. 7   a  show an embodiment of a passage conduit structure having ends formed, at one end for connection to an enclosure barrier and at the other end formed for connection for intravenous access. The embodiment of  FIG. 7   a  depicting the addition to the fluent materials of formularies, anesthetic agents, mixing of pharmaceutical preparations and drugs and the like at some point along the passage conduit structure and or the barrier enclosure. 
         FIG. 8   a  shows the embodiment of a passage conduit structure formed at both ends, at one end for connection to barrier enclosure port structures and at the other end for connection to IV access. The embodiment depicting formularies, anesthetic agents, mixing of pharmaceutical preparations and/or mixing drugs added to/with the fluent materials at some point along the passage conduit structure and or at the barrier enclosure. 
         FIG. 9  shows an embodiment of a barrier enclosure having port structures and anti-motion grips on the side. 
         FIG. 10  shows another embodiment barrier enclosure having port structures and anti-motion grip structures on the side. 
         FIG. 11  shows an embodiment of the barrier enclosure resting within a holding support means. The enclosure holder fashioned to fit conveniently within a ring support. Both enclosure support and ring are held by a form of bracket or brace. 
         FIG. 12  shows another view of the barrier enclosure resting within the holder of  FIG. 11  and showing the anti-motion structures slidingly associated with the lower portion of the holder. 
         FIG. 13  shows a blowup detail of the anti-motion structure on the side of the enclosure embodiments of  FIG. 9  and  FIG. 10  as a key and keyway type of attachable mechanism. Anti-motion structures of the barrier enclosure is shown slidably engaging the lower portion of the holder to support the side walls of the embodiment for supportive purposes. 
         FIG. 14  shows an embodiment of an barrier enclosure hermetically sealed having port structures and shaped to be supported within a ring holder. 
         FIG. 15  shows an alternative embodiment of an anti-motion support and pin holder. 
         FIG. 16  shows an embodiment of the enclosure holder having pins which feed through a plurality of support structures. 
         FIG. 17  shows a side view of what would be the barrier enclosure embodiments of  FIG. 1  and  FIG. 2  depicting the anti-motion struts/supports on both sides of the embodiment. 
         FIG. 18  shows a ring holder and an attachment to the ring holder for accepting the enclosure embodiment slidably engaging the embodiment up to the point on the embodiment where width one becomes width two.  FIG. 18  is a blow up view of a portion of the embodiment showing the slidably engagable portion of the anti-motion strut fitting into the portion of the holder. 
         FIG. 19  shows an alternative embodiment of barrier enclosures of  FIG. 1  and  FIG. 2  with this embodiment having small holes formed within the anti-motion struts for stability for pinning. 
         FIG. 20  shows the embodiment of  FIG. 19  being held within an alternative embodiment holder whereby the wholes for pinning line up for holes in the holder for stability. 
         FIG. 20   a  shows a blow up of the pinning (pin and hole) assembly whereby the holes of the anti-motion strut may be aligned with the holes of the holder for pinning there through for stability if necessary. 
         FIG. 21  shows a schematic view and a line chart of how the sterile liquid delivery embodiments of this disclosure are intended to expand the points of consumption along a continuum of care to cross into the uses not requiring sterile liquid packaging. The arrows  215 , depict the passage conduit structures interposed between coordinated manufactured coaptation between the enclosure(s) and the patient along a continuum of care. The enclosure embodiment may be similar/dissimilar, and expands the point of consumption as the passage conduit structure interposes the similar/dissimilar barrier enclosure between itself as a sterile liquid package and a non-sterile liquid package and the like. 
         FIG. 22  shows arrows of consumption/uses and arrows with the acronyms having the following meaning. EO means enclosure embodiment(s) as an origin(s). EDD means enclosure embodiment(s) as delivery destination(s). ES means enclosure embodiment(s) as a source(s). P means a patient (body) as an origin(s), as a source(s) and or as a delivery destination(s) but not intended to be in any particular order, but in the order(s) best determined by the customer.  FIG. 21  shows passage conduits of this embodiment system interposed between the sterile and the non-sterile, interposed between the clean and the dirty, interposed between the sterile liquid package and the package not manufactured for sterile liquid package (which may be the same/similar or different/dissimilar package/barrier enclosure.  FIG. 22  sows three schematics A, B &amp; C. In schematic A the circles represent the enclosure as an origin, the enclosure and a delivery destination, the enclosure as a source. It is also intended to show the patient as a potential origin, source and/or delivery destination. The arrows of schematic a are intended to depict passage conduit structures coordinated and manufactured for coaptability and connectability and interposed between origins, sources, delivery destinations and patients or any combination thereof. Example B is intended to show the enclosure as a delivery destination, and/or the enclosure as a source and/or the enclosure as an origin. Example B also intends to show the patient as a source, and/or as an origin and or as a delivery destination. The arrows of example B intend to depict passage conduit structures manufacture for coaptable connectability and interposed the enclosures and the patients as depicted by the schematic. Example C is intended to show the enclosures as a source, the enclosure as an origin, and the enclosure and the enclosure as a delivery destination. Example C also intends to show the patient as a destination, and/or as and origin, and/or as a source. The arrows of example C are intended to depict manufactured connectable and coaptable and connectable passage conduit structures made for interposition between the enclosures and the patient as depicted in example C. 
         FIG. 23  shows the system differential pressure dynamics of examples A, B &amp; C of  FIG. 22  and relates these examples of barrier enclosure consumption with positive, negative and self imposed differential pressures. The self imposed differential pressures may be initiated by wall spring memory or may be initiated by electrical/mechanical means within the enclosure-IE not from a remote source. The arrows of examples A, B &amp; C of  FIG. 23  depict passage conduit structures interposed between enclosure embodiments that may function as origins, sources, and/or delivery destinations whereby the same/similar enclosure made sold and used for consumption and manufactured for coordinated connection as a sterile liquid package includes consumption as another type of enclosure barrier. 
         FIG. 24  shows a bar chart showing point of consumption expansion in examples A, B, C, D &amp; E. A sterile liquid package has consumption value post egress of the initial sterile liquid as distributed and is depicted by the arrows showing the expanded points of consumption by ingressing and or ingressing and egressing of fluent materials as/from a source(s), as/from an origin(s) and/or as/from delivery destination(s). 
         FIG. 25  shows a schematic having to do with enclosure(s) and passage conduit structure reprocessing. It is intended to show that reprocessing may add flexibility and re-application along continuums of care and to further expand the points of consumption of the same/similar barrier enclosures and/or passage conduit structures. The reprocessing may be appropriate for certain circumstances as deemed necessary by the consumer. The straight lines of this schematic show passage conduit structures as manufactured, coapted links interposed between the origins, sources, delivery destinations, and patients interposing similar/same barrier enclosure(s) interposed between distribution of sterile liquid packages and disposal/collection of fluent materials not otherwise distributed as a sterile liquid package, under a variety of circumstances and for a plurality of dynamic events, but not limited to that. 
         FIG. 26  is a schematic made to show the flexibility and co-integration of how the embodiment(s) enclosure(s) system may be applied to the distribution consumption and disposal of barrier enclosures and passage conduit structures. This diagram is intended to teach open flexibility and application of the herein disclosed embodiment systems and the flexibility potential the consumer may utilize in its consumption, and creation of the maximum supply chain savings benefit. MMM means methods of manufacturing and materials. O means origin(s). FM means fluent material(s). S means source(s). D means destination(s). P means patient(s). 
       Schematic  FIGS. 21 through 26  show by arrows and line linkages how a barrier enclosure embodiment(s) distributed and consumed in sterile liquid package condition, meeting the regulatory and Sterility assurance requirements of the sterile liquid package industry, may be consumed and conditioned for enclosing fluent materials in the collection and disposal of fluent materials. Embodiments are show for this purpose and applied to the subject matter and the embodiments of the entire application in  FIGS. 1 through 26  disclosed herein, as well as the aforementioned provisional patent application and the aforementioned non-provisional patent application cited in the first paragraph of this provisional patent application. 
     
    
    
     DESCRIPTION OF THE DETAILED DRAWINGS 
     In  FIG. 1 , embodiment  1  has three port structures  2 . One port structure is attached to cap closure  4 . Embodiment  1  has width  2 - 6  and width  1 - 7  and length  13 . Variable height portion  8 , allows for the enclosure barrier to have different heights/volumes and still fit within the holder of  FIG. 18 . Embodiment  1  has incremental marking  17  so that fluent material flow rate may be monitored. Embodiment enclosure  1  also has anti-motion strut  10  of sufficient width  11  to maintain anti-motion support. Anti-motions strut  10  has pin hole  12 . Embodiment enclosure  1  has two width&#39;s whereby width  1 - 7  changes to width  2 - 6  at  9  producing a differential dimension ledge at  9 . This ledge forms a support  9  and contact point around the edge periphery making a contact point about the embodiment to be held in the aperture of the support holder of  FIG. 18 . 
       FIG. 2  comprises enclosure embodiment  14  having three port structures each  15  one port structure  15  is attached to cap  16 . Embodiment enclosure  14  has two widths  19  &amp;  18 , width  218  and width  1 - 19  and has length  27 . Width  1 - 19  meets width  2 - 18  at  21 , creating differential dimensions at  21 , the differential dimensions on each side of the embodiment enclosure forming the ledge(s) for support of embodiment  14  for fitting and being held by the support holder of  FIG. 18 . Embodiment  14  has variable height  26  for different manufacturable volumes of the embodiments having different overall heights and still fit within the holder support of  FIG. 18 . Embodiment  14  has incremental markings  17  so that the rate of fluent material flow may be visualized. Anti-motion struts supports  25  having sufficient width  24 , and pin hole  23 , and similar to anti-motion strut  10  of  FIG. 1  may be unitary to the enclosure or may be attached. Pin hole  23  of anti-motion strut/support  25  allow pinning and further securing to the lower holder structure of  FIG. 20 . 
     The embodiment of  FIG. 3  comprises passage conduit structure having an enlarged portion  31  with incremental marking  32  for the visualization of fluent flow rate changes. Enlarged conduit portion  31 , having length  30  and incremental marking  32  is also make of transparent clear materials. Structure  28  may be associated with a urinary drainage catheter or the like and structure  34  may be associated with the enclosure  38 . Passage conduit structure  33  may be fitted to a stopcock of valve at A, to stop flow near the enclosure barrier connection site so that fluent material drainage flow may rise in the enlarged portion  31  to monitor drainage output such as would be the case in using a urimeter, but in this embodiment the enlarged portion  31  functions as an in line urimeter. Junction A may comprise a stopcock or a valve or any other similar means of occluding passage of fluent materials during the period for which metering is desired. Similarly, simply clamping passage conduit structure at B may effect the same occlusion during the period for which occlusion is required. The enclosure barrier embodiment of  FIG. 3  has port structure  36  manufactured for coaptibility and connectability to the passage conduit structure of  FIG. 3 . 
       FIG. 4  shows another embodiment of a passage conduit structure  43 , having enlarged portion  41  and enlarged height portion  42 . The enlarged portion has incremental marking for visualization and metering the rise of fluent material flow rates. The passage conduit structure of  FIG. 4  may be associated with a urinary drainage catheter at  39 , or a wound catheter at  39  and connected to an enclosure barrier at  45 .  FIG. 4  is show to have the same stopcock, valve, or other flow occlusion means as depicted at B. 
       FIG. 5  comprises an embodiment of passage conduit structure  55 , a portion of which said structure has incremental markings  56  along length portion  54  of said conduit structure and intended to function as an inline fluent flow meter (in line urimeter but not limited to that) for measuring/metering the fluent material rise rate for determining the volume/rate of fluent material flow. Passage conduit structure  55  may be clamped at B to occlude fluent flow effecting the flow rise along conduit length  54  and incremental markings  56  may used to determine the flow rate as desired and functioning as an inline fluent material flow meter (inline urimeter but not limited to that). 
       FIG. 3   FIG. 4 , and  FIG. 5  show passage conduit structures having transparency and being made of materials clear enough for visualization of fluent materials rise along lengths  30 ,  42 , and  54  of the passage conduit structures shown. 
       FIG. 6 ,  FIG. 7 , and  FIG. 8  respectively each show enclosure barriers  69 ,  69   a  and  83 , manufactured with port structures for coaptive connectability to passage conduit structures  65 ,  71 , &amp;  77 . The passage conduit structures having ends  66 ,  72  &amp;  78  manufactured for coaptive connectability to port structures of enclosures  69 ,  69   a  and  83  at one end and intended for receiving materials from coaptive connectability to a urinary bladder drainage catheter, a wound drainage catheter or from a source-origin-delivery-destination or a health care patient as shown in  FIGS. 21 through 26 . 
       FIG. 6   a ,  7   a  &amp;  8   a  show embodiment enclosures  84 ,  100  &amp;  101  each having port structures  87 ,  94  and  103  and manufactured for coaptive connectability to passage conduit structures  88 ,  96  and  104 . Enclosures  84 ,  100  &amp;  101  are manufactured for coaptive connectability to origins sources and delivery destinations and patients as shown in the schematics of  FIGS. 21 through 26  and are intended to for coactive connectability to intravenous access through end structures  90 ,  98  &amp;  106 . Formularies, anesthesia agents, pharmaceutical preparations, mixing of drugs and preparations and administering and dosing treatments may take place along passage conduit structures  89   a  &amp; b,  97   a  &amp;  b  and  105   a  &amp;  b  or may take place at the sites of enclosures embodiment structures  84 ,  100  and  101 . 
     The embodiment of  FIG. 9  shows enclosure  108  having port structures  110 ,  111  and  109  and cap  112 . Mounted one the side of embodiment enclosure  108  shows anti-motion grip  113  having two dimensions  114  and  113 . Enclosure  108  shows incremental marking  115 . 
     The embodiment of  FIG. 10  comprises an alternative barrier enclosure  116  having overall differing shape (rounded edges) having port structures  117 , 118  and  119  and cap  120 . Incremental markings  123  are shown. Anti-motion grips  121  and  122  having two dimensions  121  &amp;  122  are associated therewith. 
       FIG. 11  shows embodiment of enclosure holder  125  which is fashioned to be held by resting/holding ring  126 . Ring support  125   a    125   b  and  125   c  are structurally attached to ring  125 . Barrier enclosure  132  slidable engages the vertical enclosure supports of  125   a    125   b  and  125   c.    
       FIG. 12  shows barrier enclosure  139  in resting position within ring holder  125 . Enclosure  139  has ports structures  142 , 141  and  140  positioned and accessible for access to passage conduit structures. Vertical support  138 , 136  and  137  slidably engage anti-motion grips as shown in  FIGS. 9 and 113  and  114  and as shown in  FIGS. 10  as  121  and  122 . The slidably engagable grip system fit is shown more visibly in blow up  FIG. 13  whereby anti-motion grip  114   m    113  and  121  and  122  are placed in slidable engagement with vertical support  136  forming a key and key hole/keyway sliding relationship. 
       FIG. 14  shows ring holder  145  supported by mount  144 . Barrier enclosure  143  has port structures  147   148  and  146  and cap  149 . 
       FIG. 16  shows an alternative embodiment of anti-motion struts. Barrier enclosure  157  has port structures  158  and  159  &amp;  160  and has anti-motion supports  156  and  155  and  154 . Stability pin  151 , 152 , and  153  are mounted to support  150  and are located and position to accept the holes associated with enclosure  157  and racked/placed on holder  150  as the pins are placed through the holes as depicted in  FIG. 15 . 
       FIG. 15  is a close up of anti-motion support  162  having hole  166  and may be made unitary or associated with enclosure housing wall  161 . The close up of  FIG. 15  shows the pin and hole relationship of pins  151 , 152 , 153  and how they would be used in pinning holes  156 , 155 , and  154  as positioned around enclosure  157  for anti-motion support means. This engagement creates a plurality of anti-motion support for enclosure  157 . 
       FIG. 17  shows embodiment  170  having width  1 - 169  and width  2 - 168 . Anti motion support  172  and  171  are intended to fit within holder slot  193  &amp;  194  of  FIG. 18 . Enclosure  167  has port structures  174 ,  175  &amp;  173 . Width  1 - 169  of embodiment  167  of  FIG. 17  is intended to correspond width  1  of embodiments enclosures  1  of  FIG. 1  and embodiment enclosure  14  of  FIG. 2 , and width one- 196  of in  FIG. 18  but width one- 196  of  FIG. 18  is slightly larger for easy accommodation of the aforementioned enclosure embodiment. Length L  191  of  FIG. 18  corresponds of length L  27  of  FIG. 2  and length L  13  of  FIG. 1  however length l  191  of  FIG. 18  is slightly larger for easy accommodation of the aforementioned enclosure embodiments. Width  1 - 169  and length (not shown but inferred by lengths  27  and  13  f  FIGS. 1 &amp; 2 ) of  FIG. 17  is intended to slide into aperture  195  in surface/space of  191  of holder  192 . Ridged surface  172   a  and  172   a  of  FIG. 17  is intended to rest on surface  191  supporting enclosure  167  in holder  192 . Holder  192  is intended to conveniently fit onto a ring  190 . Ring  190  is supported by braces  189   b  and  189   a  and mounted to support  188 .  FIG. 18   a  shows lower support  182 . Lower support  182  has slot  180  and shows slidable engagement of anti-motion support  176   a.    
       FIG. 19  shows embodiment enclosure  199  having anti-motion supports  205  which has pinning holes  204 . Enclosure  199  also has width  1 - 206  and width  2 - 203 . Embodiment enclosure  199  slidably fits into holder  212 . Holder  212  conveniently fits onto ring  213 . Lower support  214  is slotted as shown in blow up  FIG. 20   a . Lower motion support  205  has pin hole  214   a  which may be conveniently aligned with anti-motion support pin hole  204  and pin for anti-motion stability.  FIGS. 17 ,  18 ,  18   a , and  FIGS. 19 ,  20  and  20   a  are intended to show alternative enclosure holding methods and apparatus for enclosure embodiments of  FIG. 1  and  FIG. 2 . The change in width from width  1 ( 7 ,  19 ,  169 ,  206 ) to width  2 ( 6 , 18 ,  FIGS. 17-168 ,  FIGS. 19-203 ,  FIG. 20  W 2 ) creating a ridge or resting ledge for contact support to contact surface/stop  191  whereby enclosure portion  199  of  FIG. 19  may rest above the surface of aperture support  191  of  FIG. 18 . 
       FIGS. 21 through 26  show the interrelationship and integration of the distribution and delivery utilization sterile liquid/aseptic packaging manufacturing processes with/to the collection and disposal of fluent materials as described and disclosed in this application. The embodiments, apparatus and methods herein disclosed are intended for creative integration and utilization for the maximum desired/created application for supply chain efficiency potential.