CA2212807C - Leak proof tube connection site - Google Patents

Abstract

A fluidic connector (10, 110) with a leak proof connection site (11, 111) th at includes a first larger diameter portion (15 122), a second smaller diameter portion (16, 123) and a deformable buckling region (19, 124) that forms a part of both the first (15, 122) and second (16, 123) diameter portions where the two portions join. The first larger diameter portion (15, 122) forms a separate inner surface for receiving a plug (116) to securely seal off the connection site from flu id communication therethrough while the second smaller diameter portion (16, 123) is adapted to receive and securely seal different sizes of male adapters used for attaching a lumen. Finally, the deformable buckling region (19, 124) forms a structural buffer between the first (15, 122) and second (16, 123) diameter portions in order to maintain the diameter of the first larger diameter portion (15, 122) when the second smaller diameter portion (16, 123) is stretched out by prolonged insertion of a nonconforming male adapter. In addition, an adapter (132) is provided which permits flexibility in use and provides a redundant fluid seal, without exhibiting creep.

Description

LEAK PROOF TUBE CONNECTION SITE
TECHNICAL FIELD
This invention relates generally to fluidic connectors.
Specifically, the present invention relates to a leak proof connection site for fluidic connectors that is adapted to re-ceive different size male adapters for connection to a tube. More particularly, the present invention relates to a leak proof connection site that utilizes different sealing surfaces for capping the connection site and securely sealing the male adaptor therein without any attendant stretching or leaking of the connection site.
BACKGROUND ART
Fluidic connectors, such as Y-site connectors and single connectors, are well known in the art and a variety l5 of different designs have heretofore been proposed to satisfy the objectives of various applications. For example, fluidic connectors are used in enteral feeding systems where the fluidic connector acts as a connection si-to between the feeding tube lumen and the tube assembly leading to a patient and ensures uninterrupted fluid communication between the feeding system and the patient during operation.
A typical fluidic connector comprises a proximal end connection site for fluid supply or withdrawal and a distal end connection site for attachment to a lumen leading to a patient. When the lumens leading to the proximal and distal end connection sites are connected thereto, the lumens are in closed fluid communication. The proximal end connection site is typically a "female" connection site with a hollow inner portion. This hollow inner portion accommodates a "male" adaptor, through an interference fit, and provides fluid communication with the patient lumen. Further, the proximal end connection site usually incorporates a closure means where a plug tethered to the proximal end connection site is inserted into the hollow portion of the proximal end connection site in order to securely seal the lumen from S fluid communication therethrough.
A fluidic connector with distal and proximal end connection sites designed to receive a lumen which can alternatively be plugged by a cap tethered to the connector is described in U.S. Patent No. 5,242,389 to Schrader et al.
Schrader et al. describes a fluidic connector with a proximal end connection site that has an inner surface adapted to receive both a male adaptor for facilitating attachment to a lumen as well as a plug for closing off the connection site when the lumen is detached. However, using the same inner surface at the connection site to receive the male adapter and the plug suffers from a phenomena called permanent set or plastic deformation.
A phenomena referred to as plastic deformation synonomously known in the art as "creep" can occur in two ways. First, if a non-conforming male adapter that is too large is inserted into the connection site it can over-stretch the connection site, thereby leading to a permanent deformation of the connection site. Finally, a non-conforming male adaptor that is left inserted into the connection site for a prolonged period can also lead to plastic deformation. Typically, this plastic deformation or stretching of the connection site occurs because different types of male adaptors are commonly used in one type of fluidic connector with little or no conformity in size or design of the male adaptor by vendors. Thus, a nonconforming male adaptor is inserted into a proximal end connection site that is ill-suited in size to accommodate the adaptor to the extent that the adaptor begins to permanently stretch out the inner surface of the connection -site over time due to its nonconforming size. Further, this ' stretching of the connection site causes the connection site's inner surface to become unsuited for subsequent insertion of a plug because the plug no longer securely fits the stretched out connection site opening, thereby causing the connection site to leak fluid even when plugged.

Accordingly, creep is responsible for a loss of sealing function in the female when a non-conforming male adapter is _ inserted into the female receptacle for a prolonged period of time. Creep is also responsible for a loss of capping function because the part of the female_responsible for capping is actually coupled to or part of the sealing surface.

U.S. Patent No. 5,267,983 to Oilschlager et al used a tethered cap as a strap retainer to hold the male adaptor together with the proximal connection site in order to ensure a secure fit with the adaptor at all times. However, oilschlager et al did not address the attendant problem of peaking due to stretching out of the connection site opening since both the capping and sealing surfaces were the same integral structure and the dimensional integrity of. the capping surface could still be compromised when plastic deformation occurred.

Referring to FIG. 1, a prior art fluidic connector 1 is shown. The fluidic connector 1 comprises a wall 4 with patient connection site 2 atthe distal end of connector 1 and a tube connection site 3 located at the proximal end of connector 1. The tube connection site 3 is adapted to receive a male adaptor (not shown) for facilitating connection to a tubing assembly while the patient connection site 2 is adapted to connect to tubing leading to a patient.

The tube connection site 3 further includes an opening 5 which leads into a cavity 6 that is adapted to receive the male adaptor. The cavity 6 includes a sealing and plugging portion 7 which extends from the opening 5 to the patient connection site 2 and is designed to form a secure - ' interference fit with the male adaptor when the adaptor is inserted therein. The sealing and plugging portion 7 also serves as a plugging surface wherein a cap (not shown) is inserted through the opening 5 and engages a cap retaining groove 8 that closes off the opening 5 from fluid communication therethrough.
As of yet, nothing in the prior art has addressed the problem of developing a connection site for a fluidic connector that permits the use of various nonconforming male adapters to facilitate connection to a lumen without stretching out the inner surface of the connection site so that a plug will also securely fit thereto without leakage from the connection site.
To add complexity to the present situation, in Europe, reversed luer tapers are used for feeding tube connections.
In other words, in Europe, the source has a female connection. The provision of a female connection by the source is the opposite from that used in intravenous connections. The reasoning employed by such the European system is that a female connection at source ehiminates the possibility that a feeding source could be inadvertently connected to an intravenous cannula. Therefore, any universal fluidic connection solution to the creep problem would necessarily require some accommodation for the European system. Accordingly, there is not only a need in the art to develop a connection site for a fluidic connector that permits the use of non-conforming male adapters without creep, but there is also a need for one or more point-of-use adapters that would permit such a fluidic connector to be attached to any other type of connector, such as a male luer for the European market.

DISCLOSURE OF INVENTION
' In brief summary, the present invention relates to a fluidic connector with a improved connection site that 5 includes a first larger diameter portion, a second smaller diameter portion and a deformable buckling region that forms a part of both the first and second portions. The first larger diameter portion forms a separate inner surface for receiving a plug to securely seal the connection site from fluid flow communication therethrough while the second smaller diameter portion is adapted to receive and securely sea-1 different sizes of male adapters for attaching a lumen.

Finally, the deformable buckling region forms a structural buffer zone between the first and second portions that maintains the dimensions of the first larger diameter portion when the second smaller diameter portion is stretched out by the adaptor due to short or long term insertion of the adaptor therein.

Accordingly, a principal object of the present invention is to provide a fluidic connector having a first larger diameter portion whose dimensions and features will not be compromised when a second smaller diameter portion is stretched out.

Another object of the present invention is to provide a fluidic connector with a connection site having two portions of different diameters that are structurally distinct from one- another.

A further important object of the present invention is to provide a fluidic connector with smaller diameter portion that may accommodate different types and sizes of male adapters for insertion in an interference-type fit that minimizes the tendency for the connection site or the capping site to under plastic deformationand maximizes the axial retention force of the male adaptor and cap.

Another object of the present invention is to provide a fluidic connector with a first larger diameter portion that will not leak when a second smaller diameter portion thereof is stretched out.
A further important object of the present invention is to provide a fluidic connector with a deformable buckling region as a buffer between the first and second diameter portions.
These and other objects of the present invention are realized in a presently preferred embodiment thereof, described by way of example and not necessarily by way of limitation, which provides for a fluidic connector with a connection site having two portions of different diameters.
The first larger diameter portion is designed to securely receive a plug without leakage caused by attendant stretching of the connection site by an nonconforming male adaptor inserted therein and a second smaller diameter portion is adapted for securely receiving a variety of male adapters. Finally, a deformable buckling region is provided as a buffer between the first and second diameter portions that maintains the shape and size of the larger diameter portion when the smaller diameter portion is stretched out.
In accordance with a first broad aspect, the invention provides a connection site for a fluidic connector, said connection site comprising: an inner portion comprising: i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter of said second diameter portion; and a deformable region between said first and second diameter portions adapted to buckle for allowing said first diameter portion to retain the same shape when the diameter of said second diameter portion is increased.
In accordance with a second broad aspect, the invention provides a connection site for a fluidic connector, said connection site comprising: an inner portion comprising: i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter of said second diameter portion; and a deformable region forming a part of said first and second diameter portions and adapted to buckle in such a manner that when said second diameter portion stretches in a radial direction said first diameter portion translates axially.
In accordance with a third broad aspect, the invention provides a connection site for a fluidic connector, said connection site comprising: an inner portion comprising: i) a first diameter portion; ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter said second diameter portion; and a deformable region forming a part of said first and second diameter portions adapted to buckle in such a manner that allows the first diameter portion to move axially and said second diameter portion to stretch in a radial direction and adapted to allow said first diameter portion to retain its original diameter when said deformable region buckles.
In accordance with a fourth broad aspect, the invention provides a fluidic connector comprising: a connection site comprising: an inner portion comprising: i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter of said 7a second diameter portion; and a deformable region between said first and second diameter portions and adapted to buckle for allowing said first diameter portion to retain the same shape when the diameter of said second diameter portion is increased.
Additional objects, advantages and novel features of the invention will be set forth in the description which follows, and will become apparent to those skilled in the art upon examination of the following more detailed description and drawings in which like elements of the invention are similarly numbered throughout.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 shows a cross-section view of a fluidic connector with a prior art connection site;
FIG. 2 shows a section view of a fluidic connector with a connection site formed in accordance with the present invention;
FIG. 3 shows a section view of the fluidic connector of FIG. 2 with the deformable buckling region highlighted;
FIG. 4 is the prior art connection site of FIG. 1 showing in phantom how the connection site wall stretches out after prolonged insertion of a male adaptor;
FIG. 5 is the connection site formed in accordance with the present invention showing in phantom how the deformable buckling region stretches in order to maintain the dimensional stability of the capping portion;
FIG. 6 is a partial view of the connection site formed in accordance with the present invention showing how 7b the original dimensions of the deformable buckling region stretch in phantom;
FIG. 7 is a section view of a fluidic connector showing the preferred embodiment of the connection site formed in accordance with the present invention;
FIG. 8 is a plan view of the European luer adapter and the fluidic connector; and FIG. 9 is a plan view of the European luer adapter as inserted into the fluidic connector.
BEST MODE FOR CARRYING OUT THE INVENTION
Referring to FIG. 2, a fluidic connector 10 in accordance with the present invention will be discussed.
The fluidic connector 10 comprises a tube connection site 11 at its proximal end and a patient connection site 12 at its distal end. The fluidic connector 10 further comprises a wall 13 that forms an inner portion shown as hollow cavity 14 inside connector 10. The hollow cavity 14 extends between both connection sites 11, 12 and permits fluid communication therethrough. The tube connection site 11 includes a first larger diameter portion 15 and a second smaller diameter portion 16. The first larger diameter portion 15 provides an area for closing off the tube connection site 11 with a plug while the second "
smaller diameter portion 16 provides a separate surface used for securely sealing, in an interference fit, a male adaptor (not shown) when the adaptor is inserted into the tube connection site-11.
The first larger diameter,portion 15 includes an opening 17 and a cap retaining groove 18 located below opening 17 for securely engaging the cap or plug upon insertion of a plug (not shown) into opening 17 therein.
Although only one cap retaining groove l8,is shown, it is within the scope and spirit of the present invention that any suitable number of grooves 18 can be used to retain the cap. Further, the first larger diameterportion 15 is of sufficient diameter to allow a tight fit-for the cap, while permitting sufficient clearance between an inner surface 23 of portion 15 and the adaptor when the adaptor is inserted therein. Finally, the tube connection site 11 further includes a deformable buckling region 19 that forms a structural buffer zone between the first and second portions 15, 16.
Referring to FIG. 3, the deformable buckling region 19, the highlighted region of FIG. 3 that overlays a zone that partially includes both the first and second portions 15, 16 of the tube connection site 11 where the two portions 15, 16 join. Specifically, the deformable buckling region 19 is the area-beginning at an outer annular ridge 20 and ending where a curved portion 21 of the tube connection site 11 terminates. The outer annular ridge 20 serves to maintain the radial dimensional integrity of the first larger diameter portion 15 and provides termination of the buckling zone.

Referring to FIGS. 4 and 5, the operation of the deformable buckling region will be explained. As seen in FIG. 4, the original configuration of the prior art fluidic connector 1 before plastic deformation occurs is shown in solid while the configuration of that same connector 2 after the sealing and plugging portion 7 have been stretched out is shown in phantom. Without the deformable buckling region 19, the entire length of the sealing and plugging portion 7 is subject to stretching out. Leakage occurs when the 1D opening 27 is plugged because the same surface is used to both plug the tube connection site 11 as well as to form a seal against the male adaptor. Thus, when a nonconforming male adaptor is inserted into the tube connection site 11 for a prolonged period, the entire length of the sealing and plugging portion 7 is stretched out permanently in a radial direction, denoted as direction A in FIG. 4. This radial displacement of the wall 13 creates a larger diameter _ ._ aperture at the opening 17. Radial displacement of opening 17 also results in an attendant loss of axial retention 2o force when a plug is used to seal off the tube connection site 11 since the plug no longer securely fits the opening 27.
Referring to FIG. 5, the fluidic connector 20 of the present invention is shown. The original configuration of the fluidic connector 10 before insertion of a male adapter into the smaller diameter portion 16 is shown in solid, while the configuration of the connector 10 after plastic deformation has occurred is shown in phantom. When the tube connection site 21 is subjected to plastic. deformation, the second smaller diameter portion 16 is stretched radially or in the A direction, the deformable buckling region 19 deforms, with the deformation terminating at the outer annular ridge 20 and possibly resulting in translation of the first larger diameter portion 15 axially without affecting the size and shape of the larger diameter portion with respectto it's plugging function.
Referring to FIG. 6, an enlarged view of the fluidic ' connector 10 with the deformable buckling region 19 is 5 shown. In. the preferred embodiment, a male connector (not shown) is inserted into the second smaller diameter portion 16, expanding portion 16 radially in the A direction.
However, the buckling or unwrapping effect of the deformable buckling region 19 allows the portion of the first larger 10 diameter portion 15 that is adjacent to the deformable buckling region 19 to be isolated from forces that would expand it radially, even in the absence of an outer annular ridge 20. However, the addition of one or more annular ridges 20 will further isolate the first larger diameter 15 portion 15 from any forces which might expand it radially.
The axial component of the deformation of the deformable buckling region 19 can result in a change in the overall length of the first larger diameter portion 15, either longer or shorter, depending on the specific configuration of the deformable buckling region 19. The net effect of this change in length, which is shown in phantom in FIG. 6, is an axial translation of the first larger diameter portion 15 relative to the rest of the connection site. 11.
Referring to FIG. 7, the preferred enbodiment of the present invention is shown. The preferred embodiment consists of a Y-Site connector 110 comprising a tube connection site 121 at the proximal end of connector 110, a patient connection site 112 at the distal end of connector 210, and a flushing port 11.4 at the midpoint along connector 110 which is set at an angle in relation to the tube connection site 111. Further, the tube connection site 111 has a male adaptor 113 inserted therein for connection to a lumen (not shown) while the patient connection site 112 is adapted to receive a barbed connector 115 for attachment to a lumen (not shown) leading to a patient. The Y-Site connector 110 also includes a cap 116 tethered to the tube connection site 111 by an arm member 117 and is used to plug the opening 118. Finally, a luer taper adaptor 120 in combination with a flushing port cap 121 is tethered to the flushing port 114 by a flushing port arm member 119. The tube connection site 3.11 further includes a first larger diameter portion 122 and a second smaller diameter portion 123 with a deformable buckling region 124 overlaying parts of both portions 122, 123 where portions 122, 123 join. The deformable buckling region 124 includes an outer annular ridge 125 and a curved portion 126 and functions in the same manner as explained above by acting as a buffer for the first larger diameterportion 122.
Referring to FIG. 8, a fluidic connector is shown generally at 130. Fluidic connector 130 is preferably identical to or similar to ~luidic connector 10 or Y-site connector 110. Above fluidic connector 130 is a luer adapter shown generally at 132.
Luer adapter132 comprises male-to-male luer 134, optional luer skirt 136 disposed on male-to-male luer 134, tether-138 disposed at one end on male-to-male luer 134, and luer cap 140 disposed at the other end of tether 138.
Optional leer skirt 136 has internal threads (not shown) and is disposed on a hub portion 142 of male-to--male luer 134 and retained by enlarged portions 144 (only one side shown) of male-to-male luer 134. One end of tether 138 is also disposed an a hub portion 142 of male-to-male leer 134. The other end of tether 138 retains luer cap 140. Luer cap 140 has an external thread146 which is adapted to engage the internal threads of luer skirt 136. Male-to-male luer-134 itself is made from and has a graduated tube portion 148, a rib portion 150 wherein a plurality of gripping ribs 152 are provided to assist in providing a reliable connection with WO 97/21951 PCTlUS96/19773 fluitlic connector 130, a flange 154, an assembly-retaining area 156, and a male connector 158 for connecting to a female source.
Referring to FIG. 9, luer adapter 132 is shown fully inserted into fluitlic connector 130. In operation, leer adapter 132 is inserted into fluitlic connector 130 to permit male connector 158 to be presented to a female source (not shown). The interior of fluitlic connector 130 is internally graduated to accommodate various sizes of male connectors.
Graduated tube portion 148 of luer adapter 132 as shown has two different diameter portions adapted to the internal graduations in fluitlic connector 130 to provide a reliable seal between the adapter 132 and the connector 130. When luer adapter 132 is fully inserted into fluitlic connector 130, a plurality of ribs 152 present an increasing outer diameter to meet the internally graduated fluitlic connector 130. The plurality of ribs 152 are adapted to present a non-continuous circular surface area of contact to the interior of fluitlic connector 130. The surface area presented helps prevent creep or plastic deformation in fluitlic connector 130, but is adequate to permit a reliable friction fit. It is also preferred that a redundant seal system which prevents fluid leakage or introduction of foreign matter into adapter 232 is preferred. Accordingly, flange 154 of luer adapter 132 provides a function similar to a cap to seal the unfilled remainder of the opening of fluitlic connector 130 and held in place by friction fit between the inner portion of the opening of fluitlic connector 130 and a downwardly extending cylindrical portion 155 of-flange 154.
Once sealed, a -cap portion 160 for closing the opening of fluitlic connector may be cut off or otherwise removed.
Initial results obtained in accordance with the present invention show that all adapters tested above 17,593 kg/m2 {25) psi over a thirty day pressure leak test, which exceeds by over three times the specification requirement of 5630 kg/m2 (8 psi). In addition, the pull force required to remove the luer adapter 132 from fluidic connector 130 ranged from above 4.54 kg to 6.81 kg (10 pounds to 15 pounds) on average, which surpasses the typical pull force requirement of 5 pounds for solvent bonded connection in Dobhoff feeding tubes.
Although particular embodiments of the invention have been shown, it is not intended that the invention be limited thereby, instead the scope of the present invention is intended to be limited by the appended claims.

Claims (25)

CLAIMS:

1. A connection site for a fluidic connector, said connection site comprising:
an inner portion comprising:
i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter of said second diameter portion; and a deformable region between said first and second diameter portions adapted to buckle for allowing said first diameter portion to retain the same shape when the diameter of said second diameter portion is increased.

2. The connection site according to claim 1, wherein said deformable region forms a part of said first and second diameter portions, and wherein said deformable region is adapted to deform in such a manner that when said second diameter portion stretches in a radial direction said first diameter portion retains the same diameter.

3. The connection site according to claim 2, wherein the deformable region further includes one or more outer ridges and a curved portion, the curved portion being adapted to stretch in such a manner resulting in the outer ridges translating axially and contributing to the termination of a deformation.

4. The connection site according to claim 1, wherein the first diameter portion retains its original diameter when said deformable region is subjected to a radial force and displacement exerted from the inner portion of said fluidic connector.

5. The connection site according to claim 4, wherein the radial force exerted from the inner portion of said fluidic connector originates from an adaptor inserted into said connection site, said adaptor exerting the radial force against said inner portion.

6. The connection site according to claim 1, wherein the second diameter portion comprises a plurality of different size diameter segments, the second diameter portion being adapted to receive a variety of different size adaptors therein.

7. A connection site for a fluidic connector according to claim 1, further comprising:
a luer adapter having a graduated tube portion, a rib portion wherein a plurality of gripping ribs are provided to assist in providing a reliable connection with said fluidic connector, a sealing flange, an assembly-retaining area, and a connector for connecting to a source.

8. A connection site for a fluidic connector according to claim 7, further comprising:
a luer skirt disposed on said luer adapter at said assembly-retaining area;
a tether having a first end and a second end, said first end of said tether being connected to said luer adapter at said assembly-retaining area; and a luer cap connected to said second end of said tether adapted to removably attach to said connector for connecting to a source.

9. A connection site for a fluidic connector according to claim 7, wherein said flange of said adapter is provided with a cylindrical portion, said flange being adapted to form a redundant seal against leakage when said adapter is inserted into said fluidic connector.

10. A connection site for a fluidic connector, said connection site comprising:
an inner portion comprising:
i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter of said second diameter portion; and a deformable region forming a part of said first and second diameter portions and adapted to buckle in such a manner that when said second diameter portion stretches in a radial direction said first diameter portion translates axially.

11. The connection site according to claim 10, wherein the deformable region comprises an outer ridge and a curved portion, the curved portion being adapted to stretch in such a manner that allows the outer ridge to move axially.

12. The connection site according to claim 10, wherein the first diameter portion retains its original diameter when said deformable region is subjected to a radial force exerted from said second diameter portion of said fluidic connector.

13. The connection site according to claim 10, wherein a force exerted from within said fluidic connector originates from an adapter inserted into said connection site, said adapter being adapted to exert a radial force against said second diameter portion.

14. The connection site according to claim 10, wherein the second diameter portion comprises a plurality of different size diameter segments, the second diameter portion being adapted to receive a variety of different size adaptors therein.

15. A connection site for a fluidic connector according to claim 10, further comprising:
a luer adapter having a graduated tube portion, a rib portion wherein a plurality of gripping ribs are provided to assist in providing a reliable connection with said fluidic connector, a sealing flange, an assembly-retaining area, and a connector for connecting to a source.

16. A connection site for a fluidic connector according to claim 15, further comprising:
a luer skirt disposed on said luer adapter at said assembly-retaining area;
a tether having a first end and a second end, said first end of said tether being connected to said luer adapter at said assembly-retaining area; and a luer cap connected to said second end of said tether adapted to removably attach to said connector.

17. A connection site for a fluidic connector according to claim 15, wherein said flange of said adapter is provided with a cylindrical portion, said flange being.
adapted to form a redundant seal against leakage when said adapter is inserted into said fluidic connector.

18. A connection site for a fluidic connector, said connection site comprising:
an inner portion comprising:
i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter said second diameter portion; and a deformable region forming a part of said first and second diameter portions adapted to buckle in such a manner that allows the first diameter portion to move axially and said second diameter portion to stretch in a radial direction and adapted to allow said first diameter portion to retain its original diameter when said deformable region buckles.

19. The connection site according to claim 18, wherein the deformable region comprises an outer ridge and a curved portion, the curved portion being adapted to stretch due to a radial force in such a manner resulting in the outer ridge stretching axially.

20. The connection site according to claim 18, wherein a force exerted from within said fluidic connector originates from an adapter inserted into said connection site, said adapter exerting a radial force against said second diameter portion.

21. The connection site according to claim 18, wherein the second diameter portion comprises a plurality of different size diameter segments, the second diameter portion being adapted to receive a variety of different size adaptors therein.

22. A connection site for a fluidic connector according to claim 18, further comprising:
a luer adapter having a graduated tube portion, a rib portion wherein a plurality of gripping ribs are provided to assist in providing a reliable connection with a fluidic connector, a sealing flange, an assembly-retaining area, and a connector for connecting to a source.

23. A connection site for a fluidic connector according to claim 22, further comprising:
a luer skirt disposed on said luer adapter at said assembly-retaining area;
a tether having a first end and a second end, said first end of said tether being connected to said luer adapter at said assembly-retaining area; and a luer cap connected to said second end of said tether adapted to removably attach to said connector.

24. A connection site for a fluidic connector according to claim 22, wherein said flange of said adapter is provided with a cylindrical portion, said flange being adapted to form a redundant seal against leakage when said adapter is inserted into said fluidic connector.

25. A fluidic connector comprising:
a connection site comprising:
an inner portion comprising:
i) a first diameter portion; and ii) a second diameter portion adjacent to said first diameter portion, said first diameter portion having a larger diameter than a diameter of said second diameter portion; and a deformable region between said first and second diameter portions and adapted to buckle for allowing said first diameter portion to retain the same shape when the diameter of said second diameter portion is increased.