VASCULAR ACCESS DEVICE NON-ADHERING MEMBRANES

Abstract

A medical device may include a vascular access device having a body and a membrane of the body. The membrane communicates with a pathogenic environment and discourages adhesion of a pathogen to the membrane. A method of discouraging a pathogen from residing on the membrane of a vascular access device includes providing a vascular access device with a body having a membrane and discouraging a pathogen from residing on the membrane.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

In order that the manner in which the above-recited and other features and advantages of the invention are obtained will be readily understood, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. These drawings depict only typical embodiments of the invention and are not therefore to be considered to limit the scope of the invention.

FIG. 1 is a perspective view of an extravascular system connected to the vascular system of a patient.

FIG. 2 is a cross section view of a vascular access device with a porous septum.

FIG. 3 is a cross section view of a vascular access device with a septum having a reservoir and channels.

FIG. 4 is a side view of a vascular access device connected to a cross section view of a vacuum source.

FIG. 5 is a partial cross section view of the vascular access device of FIG. 4.

FIG. 6 is a close-up, cross section view of a porous layer of the vascular access device of FIG. 4.

FIG. 7 is a close-up, cross section view of a porous layer of the vascular access device of FIG. 4 with fragmented pathogens.

FIG. 8 is a cross section view of a vascular access device having a gaseous membrane.

FIG. 9 is a close-up, cross section view of the gaseous membrane of FIG. 8.

DETAILED DESCRIPTION OF THE INVENTION

The presently preferred embodiments of the present invention will be best understood by reference to the drawings, wherein like reference numbers indicate identical or functionally similar elements. It will be readily understood that the components of the present invention, as generally described and illustrated in the figures herein, could be arranged and designed in a wide variety of different configurations. Thus, the following more detailed description, as represented in the figures, is not intended to limit the scope of the invention as claimed, but is merely representative of presently preferred embodiments of the invention.

Referring now to FIG. 1, a vascular access device (also referred to as an extravascular device, intravenous access device, access port, and/or any device attached to or functioning with an extravascular system) 10 is used to introduce a substance via a catheter 12 across the skin 14 and into a blood vessel 16 of a patient 18. The vascular access device 10 includes a body 20 with a lumen and a septum 22 placed within the lumen. The septum 22 has a slit 24 through which a separate extravascular device 26, such as a syringe, may introduce a substance into the vascular access device 10.

The device 10 also includes a membrane (discussed with reference to the figures below) integrated or compounded with, in, and/or on the body 20 of the device 10, an extravascular system 28, and/or septum 22. The membrane discourages, inhibits, prevents, or otherwise limits a pathogen from adhering to the membrane. By discouraging pathogen adhesion, the non-adhering membrane represses the pathogen by preventing or limiting pathogen colonization and proliferation into a biofilm and/or harmful culture. The membrane represses at least one pathogen to decrease the incidence of blood stream infections in patients to whom the vascular access device 10 or any other device on an extravascular system 28 is attached.

As described throughout this specification, pathogens include any agent that causes or facilitates a disease, infects, or otherwise harms or has the potential to harm a patient or host if received into the vascular system of that patient or host. A pathogen includes a pathogen, bacterium, parasite, microbe, biofilm, fungus, virus, protein feeding a pathogen, protozoan, and/or other harmful microorganisms and/or agents and products thereof. The membrane discourages a pathogen from adhering and/or represses pathogenic activity to prevent the proliferation, growth, or organization of a harmful biofilm by any one or combination of the following actions: removing, dislodging, repelling, resisting, detaching, loosening, unbinding, unfastening, releasing, separating, dividing, disconnecting, and/or freeing from a pathogen from a surface of the device 10 and/or any other similar process or action.

A pathogen may enter the device 10 or system 28 in any of a number of ways. For example, a pathogen may reside within the device 10 or system 28 prior to first use. A pathogen may also be introduced into the device 10 from the external surface of the device, the external surface of a separate device 26, and/or the surrounding environment when a structure such as a tip 30 of the separate device 26 is inserted into the device 10 through the slit 24 of the septum 22. A pathogen may be introduced within fluid that is infused into the system from a separate device 26. Finally, a pathogen may be introduced from a blood vessel 16 into the system 28 by entering through the end 32 of the catheter 12 during a blood draw or a period of blood reflux when the device 10 is in use. The membrane may thus be integrated, compounded, and/or placed in or on any surface, structure, or body of the entry, junction is, and/or fluid path of the system 28 in order to discourage pathogen adhesion and repress pathogenic activity, as desired.

Referring now to FIG. 2, a vascular access device 10 includes a body 20 and a septum 22 residing on an inner surface of the body 20. The septum 22 and/or the body 20 are examples of membranes that communicate with a pathogenic environment and discourage adhesion of a pathogen to the membrane in order to repress the activity of the pathogen. The septum 22, for example, includes multiple pores 34 through which an oil or other lubricant is transferred to an exterior surface of the septum 22, such as the surface of the slit 24 of the septum 22. The oil or lubricant may also include an antimicrobial agent or other fluid that may be transferred across the septum 22 membrane through the pores 34. The antimicrobial agent may be any agent capable of repressing the activity of a pathogen, including any of the antimicrobial agents listed in the following Table 1.

The material of the septum 22 is preferably a silicone capable of bleeding or otherwise eluding a lubricant through its pores. The material of the septum 22 may be regulated or otherwise coated with a material capable of limiting the porosity of the material. Thus, the rate at which lubricant is exuded to a pathogenic surface of the septum 22 can be controlled to provide an environment that is optimal for discouraging adhesion of a pathogen to the surface. Similarly, a surface of the septum 22 that is mechanically attached or otherwise connected to the body 20 may include a material which limits or eliminates the porosity of the material on those surfaces. Thus, at the mechanical connection between the septum 22 and the body 20, the septum 22 will not be lubricated, preventing any unwanted slipping between the septum 22 and the body 20.

TABLE 1
	Antimicrobial Mechanism of
Technology/Company	Action	Active Ingredient
Alexidine	Bisbiguanide/Antiseptic	Alexidine
AMERICAL	Halogen/Antiseptic	Iodine
(Merodine)
Angiotech	Antimicrobial/	5-Flurouracil
Pharmaceuticals	Antineoplastic
Apacidar (SGA)	Metals & Salts	Silver
Arglaes (Giltech)	Metals & Salts	Silver
Arrow Howes CHG	Bisbiguanide/Antiseptic + antibiotic	Chlorhexidine and Silver
and AgSD		Sulfadiazine
Bactifree	Metal & Salts	Silver
Bacterin	Metal	Silver Hydrogel
BASF PVP-I Dusted	Halogen/Antiseptic	Iodine
Gloves BD
Baxter American	Antiseptic and	Benzalkonium Chloride
Edwards	Anticoagulant	complexed Heparin
Benzalkonium	Quaternary	Benzalkonium Chloride
Chloride	Ammonium/Antiseptic
Benzethonium	Quaternary	Benzethonium Chloride
Chloride	Ammonium/Antiseptic
Bioshield (CATO	Halogen/Antiseptic	Iodine
Research)
BisBAL	Metal, mercury	Bismuth and 2,3
		dimercaptopropanol
		a.k.a.dimercaprol, or British
		anti-lewisite
CATO Research	Halogen/Antiseptic	Iodine
(Bioshield)
Chlorhexidine (and its	Bisbiguanide/Antiseptic	Chlorhexidine
salts)
Ciprofloxacin	Antibiotic	Ciprofloxacin
TDMAC Complex
BD
Cooke	TDMAC bound Antibiotic	Any antibiotic
Cosmocil	Bisbiguanide/Antiseptic	Cosmocil
Cyclodextrin	Nonstick surface	Cyclodextrin
Daltex	Bisbiguanide/Antiseptic	Chlorhexidine and Silver
		Sulfadiazine
Dicloxacillin	Antibiotic	Dicloxacillin
TDMAC Complex
BD
EDTA, EGTA	Calcium Chelator	EDTA, EGTA
Epiguard (Iodine)	Halogen/Antiseptic	Iodine
Epitope (Iodine)	Halogen/Antiseptic	Iodine
ExOxEmis	Oxidative enzymes	Myeloperoxidase and
		Eosinophil Peroxidase
Fusidic Acid	Antibiotic	Fusidic Acid
TDMAC Complex
BD
Gamma A	Specific Antibodies	Specific Antibodies
Technologies
Giltech	Metal & Salts	Silver
Glyzinc	Metals & Salts	Zinc
Gold	Metal & Salts	Gold
Healthshield	Metal & Salts
Heparin-	Antimicrobial/
Benzalkonium	Antithrombogenic
Chloride
Hexyl Bromide	Metals & Salts	Hexyl Bromide
Implemed (Ag/Pt)	Metal & Salts	Silver/Platinum
Intelligent Biocides	Metals & Salts	Silver
Iodine	Halogen/Antiseptic	Iodine
Iodine Tincture	Halogen/Antiseptic	Iodine
Irgasan	Phenolic/Antiseptic	Triclosan
Johnson-Matthey	Metal	Silver
Kinetic Concepts	Metals & Salts	Silver
Luther Medical	Antibiotic	Polymyxin B
Lysozyme	Enzymatic Antibiotic
Mediflex	Bisbiguanide/Antiseptic	Chlorhexidine/Isopropanol
Chlorhexidine
Gluconate Tincture
Merodine	Halogen/Antiseptic	Iodine
Microban	Antiseptic Polymer	Triclosan
Microbia	Antibiotic	“Natural” polypeptides
MicroFre	Metal & Salts
Minocycline	Antibiotic	Minocycline Rifampin
Rifampin
Minocycline-EDTA	Antibiotic	Minocycline EDTA
Morton Bloom	Cidal Lipids	Free fatty acids
Novacal	Neutrophil Cidal Factors	Oxidative Enzymes
Octenidine	Bisbiguanide/Antiseptic	Octenidine
Oligon (Implemed	Metal & Salts	Silver/Platinum
Ag/Pt)
Olin Chemicals	Metal & Salts	Zinc
Omacide	Metal & Salts	Zinc
Omni Medical	Heterologous Antibodies	Antibodies
Orthophenyl phenol	Phenolic/Antiseptic	Orthophenyl phenol
(Lysol)
Phosphorus	Antimicrobial Polymer	Phosphorus
Polymyxin B (Luther)	Antibiotic
PVP-I (Iodine)	Halogen/Antiseptic	Iodine
Quorem Sciences	Cell-signalling	Peptides
Rifampin	Antibiotic	Rifampin
Sangi Group America	Metal & Salts	Silver
SGA	Metal & Salts	Silver
Silver Chloride	Metal & Salts	Silver
Silver Nitrate	Metal & Salts	Silver
Silver Oxide	Metal & Salts	Silver
Silver Palladium	Metal & Salts	Silver
Spi-Argent	Metal & Salts	Silver
Spire	Metal & Salts	Silver
Surfacine	Metal & Salts	Silver
TCC (Triclocarban)	Phenolic/Antiseptic	Triclocarban
TCS (Triclosan)	Phenolic/Antiseptic	Triclosan
TDMAC	Antibiotics	Cephazolin, Cipro.,
		Clindamycin, Dicloxacillin,
		Fusidic Acid, Oxacillin,
		Rifampin
Triclocarban	Phenolic/Antiseptic	Triclocarban
Triclosan	Phenolic/Antiseptic	Triclosan
Vancomycin	Antibiotic	Vancomycin
Vancomycin-Heparin	Antibiotic	Vancomycin-Heparin
Vibax	Phenolic/Antiseptic	Triclosan
Vitaphore CHG	Bisbiguanide/Antiseptic	Chlorhexidine
coating
Vitaphore Silver Cuff	Metal & Salts	Silver
Zinc	Metal & Salts	Zinc
Zinc Omadine	Metal & Salts	Zinc

Referring now to FIG. 3, a vascular access device 10 includes a body 20 and a septum 22 housed on the inner surface of the body 20. The septum 22 is a membrane including at least one reservoir 36 and multiple channels 38 in communication with the reservoir 36. The channels 38 function as pores similar to the pores 34 of FIG. 2. The channels are capable of transferring an antimicrobial agent, such as the agents set forth in Table 1, across the membrane of the septum 22 to a surface of the vascular access device 10. As the vascular access device 10 is accessed, the antimicrobial agent is transferred from the reservoir 36 through the channels 38 to the inner surface of the septum 22.

For example, the vascular access device 10 may be accessed by a separate device 26, such that the tip 30 of a separate device 26 (FIG. 1) is inserted into the slit 24 of the septum 22. As the tip 30 is inserted through the slit 24, the walls of the septum 22 will be forced outward toward the body 20 of the device 10. As the walls are forced outward, the reservoir 36 will be compressed, forcing the antimicrobial agent through each of the channels 38 and onto the surface of the slit 24. Thus, every time the device 10 is accessed, the pressure change within the reservoir 36 caused by the geometrical changes of the septum 22 causes the antimicrobial agent and/or any oil or lubricant residing therein to squeeze, move, spill, or otherwise be transferred into the main path of the slit 24 from the channels 38.

The embodiments described with reference to FIGS. 2 and 3 thus describe two alternate embodiments capable of providing a membrane that discourages a pathogen from adhering to a surface of a vascular access device. By providing oils or other lubricants and providing antimicrobial agents on a surface of the device 10 through a membrane, a pathogen that would otherwise be likely to attach to such surface and reside thereon, will be either killed or unable to attach to the surface as a result of its modified characteristics.

Referring now to FIG. 4, a vascular access device 10 may be coupled with a vacuum source 40, such as a syringe, in order to pull a pathogen from the interior of the device 10 through one or more pores of the device 10 and into the vacuum source 40. The vacuum source 40 accesses the vascular access device 10 through a port 42 of the device 10.

In use, the device 10 may be clamped at location 44 downstream of the device 10, and the vacuum source 40 may then pull fluid from the device 10 through the port 42 and into the vacuum source 40. By clamping the device 10 downstream at location 44, an operator can avoid any unwanted reflux of fluid from the location 44 downstream up into the device 10 and ultimately into the vacuum source 40.

Referring now to FIG. 5, a partial cross section view of the device 10 of FIG. 4 is shown. The cross section reveals the port 42 providing a fluid exit to pathogens 46 that are removed from the device 10. The pathogens 46, such as bacteria, are transferred from the interior chamber 48 of the device 10, across a membrane of multiple pores 50, through the access port 42, and into the vacuum source 40.

Referring now to FIG. 6, the porous layer 50 of the vascular access device 10 of FIGS. 4 and 5 is shown in close-up, cross section view. The porous layer 50 reveals multiple pores that are smaller than a bacterial biofilm 52 that has started to form on the interior surface 54 of the porous layer 50. The biofilm 52 is located on the interior surface 54, which is in turn located within the interior chamber 48 of the vascular access device 10. Each of the individual pores 56 of the porous layers 50 are preferably smaller than the neighboring pathogenic structure, the biofilm 52.

Referring now to FIG. 7, the porous layer 50 of FIG. 6 is shown in similar close-up, cross section view with the biofilm 52 broken into smaller pathogenic fragments 58. The pressure caused by vacuum source 40 has caused the biofilm 52 to break up, or to be sheared, and forced into separate channels or pores 56. The vacuum source 40 thus pulls through a backside of the device 10, through the access port 42, causing the biofilm 52 to break up into individual fragments 58 and be removed from the interior chamber 48, which is part of the fluid path of the device 10 to a patient.

The material forming the walls of the porous layer 50, the size and shape of the pores 56, and the size and shape of the walls of the porous layer 50 may be adjusted as preferred in order to provide a variety of embodiments capable of shearing a pathogen, pulling a pathogen and/or a portion of a pathogen into at least one pore, and/or discouraging adhesion of a pathogen to a membrane of a vascular access device. For example, the ends of the walls of the porous layer 50 at interior surface 54 may be pointed in order to provide more of a cutting surface capable of shearing, puncturing, or otherwise separating the biofilm 52 and/or a single pathogen cell when the vacuum source 40 exerts vacuum force through the pores 56 of the porous layer 50. Further, since many bacteria are approximately one micron in diameter, the diameter of the individual pores 56 may be less than one micron in diameter in order to encourage the dissection of a bacterium as it enters into one or more pores 56 under the influence of vacuum pressure.

Alternatively or additionally, the diameter of the individual pores 56 may be slightly larger than one micron, providing access to only a single cell pathogenic, and thus encouraging the single cell to remain in a live state and be removed from the biofilm 52, thus separating it from other neighboring bacterial cells. In its live state, the bacterial cell can later be analyzed to determine the characteristics of the pathogen that was residing within the device 10. Based on those results, an operator may administer appropriate treatment to the device 10 and/or the patient to which the device 10 is attached.

Referring now to FIG. 8, a vascular access device 10 includes a membrane 60 located near the interior chamber 48 of the device 10. A close-up, cross section view of the membrane 60 is shown and further described with reference to FIG. 9.

Referring now to FIG. 9, the membrane 60 of the vascular access device 10 described with reference to FIG. 8 is shown in close-up, cross section view. The membrane 60 is formed of multiple sequential structures 62, each with a minimal surface area at its tip 64. The structures 62 are separated by pores 66 between each of the structures 62. The pores 66 house and/or emit a biocompatible gas, capable of traveling through the pores 66, and forming the large majority of the barrier of the membrane 60. The gas 68 housed within each pore 66 is preferably a biocompatible gas capable of being redissolved in the lungs of a patient.

As shown in FIG. 9, the surface area on the tip 64 of a structure 62, which is between two pores 66, is less than the surface area of the total attaching surface of a pathogen 70. Further, the width of an individual pore 66 may be at least twice the diameter of a pathogen 70. Depending upon the cohesive properties of the fluid 72 housed within the interior chamber 48, each of the gas bubbles formed within the pores 66 will form a dome of varying dimensions arching from the tip 64 of one structure 62 to the tip 64 of a neighboring structure 62. In this manner, the gas 68 of the pore 66 forms the majority of the barrier of the membrane 60, thus providing little to no mechanical surface to which the pathogen 70 may attach.

As the gas 68 travels through the pores 66 and into the interior chamber 48, the gas bubbles 68 will force any pathogen 70 that has attached to a tip 64 to be removed from the tip 64 and into the fluid 72. A pathogen 74 is thus shown having been removed from a tip 64 under the influence of a gas bubble 76. The pathogen 74 is removed from the surface of the membrane 60 before the pathogen 74 is able to colonate or otherwise develop, organize, or proliferate in order to form a harmful biofilm that would cause infection, injury, or other harm to a patient.

The gas bubbles 68, as mentioned earlier, may be at least twice the diameter of the diameter of a pathogen. For example, a pathogen having a one micron diameter may be removed by a gas bubble having a 2 to 3 micron diameter. The gas bubbles 68 may originate from any source of gas, either through a gas line attached to the vascular access device, or through cells neighboring the membrane 60. The cells neighboring the membrane 60 may include any living cell, chemical reaction, electrochemical reaction, or any other process capable of generating gas as a byproduct.

The embodiment described with reference to FIGS. 8 and 9 thus provides a membrane 60 capable of providing minimal surface area to which a pathogen may attach. By providing a membrane that is primarily gaseous, the pathogen will either bounce off or slide past the majority of the membrane and will only attach, if at all, at certain structural tips of the membrane. After the pathogen has attached to these tips, it will be too distant from a neighboring tip in order to combine and grow with another pathogenic friendly substance on a neighboring tip. Further, as gas is emitted through the pores of the membrane 60, the pathogens are forced from the tips into the interior chamber 48 of fluid path, further directing the pathogens, in their harmless state, ultimately into the patient.

The speed at which gas is transferred through the pores of the membrane 60 may be adjusted depending on the type of gas that is used, the type of pathogen that is likely to be present within the interior chamber 48, the type of treatment being administered to a patient, or other factors as determined by an operator of the device 10. For example, a high speed of gas 68 flow through the pores 66 of the membrane 60 will provide a very vigorous and turbulent environment in which a pathogen is very unlikely to settle and attach to the tips 64 of a structure 62. However, if an operator desires, the operator may slow the rate at which gas 68 is infused into the interior chamber 48, and will thus limit the amount of gas that is transferred into the vascular system of a patient. An operator may also prime the fluid line attached to the device 10 in order to remove any gas used or infused through the membrane 60. The device 10, or any device attached thereto, may also include a bubble trap, such as an IV filter, downstream of gas to trap gas bubbles prior to their entry into the vascular system of a patient. Thus, an operator may remove the gas before it enters into the vascular system of a patient.

The embodiments described with reference to FIGS. 4 through 9 may be modified to provide alternate flow of fluid and/or gas in order to provide a membrane capable of discouraging a pathogen from adhering to a vascular access device. For example, the fluid flow of the embodiments described with reference to FIGS. 4 through 7 may be reversed in order to provide a membrane that infuses both fluid and/or gas along with pathogens and/or biofilms off the interior surface 54 and into the interior chamber 48 and fluid path of the device 10. As another example, the embodiment described with reference to FIGS. 8 and 9 may be altered to provide an embodiment that reverses the flow of gas and/or fluid through the pores 66 of the membrane 60. In this alternate embodiment, the membrane 60 will pull and/or shear pathogens and/or biofilms into the pores 66 as a vacuum force is exerted upon them.

The present invention may be embodied in other specific forms without departing from its structures, methods, or other essential characteristics as broadly described herein and claimed hereinafter. The described embodiments are to be considered in all respects only as illustrative, and not restrictive. The scope of the invention is, therefore, indicated by the appended claims, rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims

1. A medical device, comprising: a vascular access device including a body and a membrane of the body,wherein the membrane communicates with a pathogenic environment, andwherein the membrane discourages biofilm formation.

2. The medical device of claim 1, wherein the membrane includes pores, wherein the vascular access device includes an antimicrobial fluid, and wherein the antimicrobial agent is transferred across the membrane through the pores.

3. The medical device of claim 2, wherein the pores of the membrane are canals.

4. The medical device of claim 3, wherein the vascular access device further includes a reservoir, and wherein the antimicrobial agent is housed within the reservoir.

5. The medical device of claim 2, wherein the antimicrobial agent is transferred as the vascular access device is accessed by a separate device.

6. The medical device of claim 1, further comprising a vacuum source in communication with the membrane, wherein the membrane includes at least one pore, and wherein the vacuum source pulls the pathogen into one or more of the at least one pore.

7. The medical device of claim 6, wherein the membrane shears the pathogen as it is pulled into one or more of the at least one pore.

8. The medical device of claim 1, wherein the membrane includes pores, wherein the vascular access device includes a lubricant, and wherein the lubricant is transferred across the membrane through the pores.

9. The medical device of claim 1, wherein the membrane includes pores, wherein each pore houses a biocompatible gas bubble, and wherein the pores are separated by a minimal surface area of the membrane.

10. The medical device of claim 9, wherein the surface area between two pores of the membrane is less than the attaching surface area of a pathogen.

11. The medical device of claim 10, wherein the width of the each of the pores is at least twice the diameter of a pathogen.

12. A method of discouraging a pathogen from residing on the membrane of a vascular access device, comprising: providing a vascular access device with a body, wherein the body includes a membrane at a location of the body that is in communication with a pathogenic environment, anddiscouraging a pathogen from residing on the membrane of the vascular access device.

13. The method of claim 12, wherein discouraging includes transferring an antimicrobial agent across the membrane.

14. The method of claim 12, wherein discouraging includes pulling the pathogen across the membrane.

15. The method of claim 12, wherein discouraging includes shearing the pathogen.

16. The method of claim 12, wherein discouraging includes transferring a lubricant across the membrane.

17. The method of claim 12, wherein discouraging includes coating the membrane with biocompatible gas bubbles.

18. A medical device, comprising: means for accessing the vascular system of a patient, andmeans for discouraging biofilm formation on the medical device,wherein the pathogen resides near the means for accessing the vascular system of a patient,wherein the means for accessing the vascular system includes a body, andwherein the means for discouraging biofilm formation includes a membrane of the body of the means for accessing the vascular system of a patient.

19. The medical device of claim 18, wherein the membrane repels the pathogen.

20. The medical device of claim 18, wherein the membrane attracts the pathogen.