|Title of Invention||
"SYRINGE ASSEMBLY HAVING A SYRINGE TIP CAP"
|Abstract||A tip cap 10 is provided comprising a base portion 16 having an upper surface 16a and a lower surface 16b, a body 12 having a top wall 14 with a non-circular cross-section extending from the upper surface 16a, and a shaft 18 extending from the lower surface 16b. A syringe assembly is provided comprising a syringe 200 comprising a barrel, and a syringe tip 220, extending through the barrel and a connector 230 provided on the syringe tip 220. The syringe assembly further comprises a tip cap 10 for sealingly covering the syringe tip 220 and comprising a base portion 16 having an upper surface 16a and a lower surface 16b, a body 12 having a top wall 14 with a non-circular cross-section extending from the upper surface, 16a and a shaft 18 extending from the lower surface 16b having connection means 20 for attaching to the syringe tip 220.|
|Full Text||SYRINGE ASSEMBLY HAVING A SYRINGE TIP CAP
CROSS-REFERENCE TO RELATED APPLICATIONS
 This application is a continuation-in-part of U.S. Design Application No.
29/180,313, filed on April 22,2 003, which is incorporated by reference herein.
BACKGROUND OF THE INVENTION
1. Field of the Invention
 This invention relates to a tip cap for closure of the opening of a liquid filled .
container, and more particularly, to a rip cap for a syringe.
2. Description of Related Art
 Conventional syringes each include a barrel having an open proximal end and
an opposed distal end. A cylindrical wall extends between the ends and defines a substance
retaining chamber. An elongate tip, commonly referred to as a luer, projects from the distal
end of the syringe barrel and includes a narrow passage, which communicates with the
substance-retaining chamber of the barrel. A plunger may be inserted into the open proximal
end of the syringe barrel for sliding fluid-tight engagement with the cylindrical chamber wall.
Sliding movement of the plunger in a distal direction urges fluid in the chamber through the
passage in the tip. Conversely, sliding movement of the plunger in a proximal direction
draws fluid through the passage in the tip and into the chamber of the syringe barrel.
 Conventional syringe barrels typically are made of plastic or glass. Glass
exhibits lower gas transmissivity than plastis. Thus, glass syringe barrels are used for
medications that are particularly susceptible to interaction with ambient gases. Glass syringe barrels also are preferably used for medications that are pre-filled into the syringe barrel and stored for a considerable period of time prior to use.
 Such syringes may further include a needle assembly with a needle cannula
having a proximal end, a pointed distal end and a lumen extending axially therethrough. The needle assembly commonly includes a hub which is engageable with mounting means on the syringe barrel for selectively placing the lumen of the needle cannula in fluid communication with the passage through the tip of the syringe barrel. Alternatively, the needle cannula may be rigidly fixed or "staked" directly to the syringe barrel.
 Medications that are pre-filled into a syringe barrel must be sealed to prevent
contamination or loss of the medication prior to use. Seals also prevent health care workers from being needlessly exposed to medications. Where a needle is not staked to the syringe body, the prior devices have included stoppers or closures mounted over the tip at the distal end of the syringe barrel, referred to as tip caps, to prevent leakage and to avoid contamination of the medication. When a pre-filled syringe is capped with a tip cap, it is especially important that a good seal be maintained. This is usually achieved by tightly affixing the tip cap to the syringe. However, when overly tightened the tip cap can be difficult to remove. Futhermore, a pre-filled syringe is may be autoclaved after filling and capping to ensure a sterile package for the contents. The autoclaving procedure however, can also have the side effect of interactions between the tip cap to the syringe, thereby further increasing the difficulty in removing the cap.
 The prior art tip cap is removed from the syringe tip shortly prior to usage of
the syringe, and the hub of the needle assembly is securely engaged with the luer and/or luer collar or other mounting means adjacent the exposed tip of the syringe barrel. For example, the needle hub may be threadedly engaged within a luer collar such that the lumen of the needle cannula communicates with the exposed tip of the syringe barrel, such as with the configuration sold by the assignee herein under the trademark "Luer-Lok".
 Current tip caps used to seal the liquid opening of the syringe barrel, are
typically a one-piece design having a round cap wall design. The mechanical advantage of a screw-type threaded cap is translation of a rotational force to an axial force, resulting in wedging the sealing mechanism of the tip cap onto the luer of the container, and forming a tight seal due to the interference fit between the sealing mechanism and the luer. With the current tip caps, the torque required to seal and unseal the bottle is generated at least partially by the friction created when the user applies a gripping force to the outside of the cap wall in order to rotate the cap.
 A problem associated with the prior art tip cap design has been the user must
apply a gripping force to grasp the circular cap by exerting a force normal to the cap walls at the point of contact with sufficient force to hold the cap from slipping, as well as applying a twisting force (a torque) for rotating the cap about its axis. This can be difficult for some users who lack dexterity or strength especially considering the small size of the typical tip cap or in the case where the tip cap is in excessively tight engagement with the syringe barrel. The difficulty in using tip caps according to prior art design is that the user must exert forces on the tip cap at right angles to both grasp and rotate the tip cap simultaneously.
 A need exists, therefore, for an improved syringe tip cap where the ability to
attach and detach the tip cap is made easier by providing a tip cap that is easier to grip while simultaneously applying torque to rotate the tip cap. In particular, it would be advantageous to provide a tip cap with a non-circular, for example elliptical, shaped gripping surface that provides the user with a surface to grip the cap and apply force to the tip cap tangential to the axis of rotation without having to also apply a gripping force.
SUMMARY OF THE INVENTION
 In contrast to the prior devices discussed above, it has been found that a tip
cap which provides the user with enhanced mechanical advantage for rotating the cap in order to affix it to a syringe can be constructed in accordance with the present invention. Specifically, the tip cap of the present invention includes a non-circular cross-sectional shape that provides a gripping surface for providing the user with extra leverage to rotate the cap.
 The present invention provides a syringe tip cap assembly for closing a
syringe such as a pre-filled syringe barrel. The tip cap includes a tip cap body having a non-circular top wall, a base sealing surface and a depending shaft, which may be threaded, for attachment of the tip cap to a syringe. The opening and closing of a threaded tip cap is accomplished by imparting torque to the cap tangential to the axis of rotation to cause the cap to rotate and thereby open or close by engaging the helical threads of the cap and container to
raise or lower the cap. The force imparted to the cap is applied by the user by gripping the perimeter of the cap.
 The tip cap of the present invention makes it easier and more effective for the
user to apply the rotational force needed to turn the cap and thus open and close it. The non-
circular shaped gripping area provides a surface for the application offeree directly tangential to the axis or rotation of the cap. The force is applied to the tip cap tangential to the axis of rotation at a distance from the axis. Therefore, the non-circular tip cap acts as a lever arm to multiply the force applied to the tip cap. In addition, because of the non-circular shape, the user need not apply a normal force to the sides of the cap in order to grip the cap as is the case with prior art designs.
 An advantage of the tip cap of the present invention is that it provides the user
with increased mechanical advantage for rotating the cap.
 Another advantage of the tip cap of the present invention is that the outer
surface of the tip cap contains features to enhance handling and grip for the user, and to provide a comfortable gripping surface that will not cut into the users fingers.
 The present invention is therefore directed to a tip cap comprising a base
portion having an upper surface and a lower surface, a body having a top wall with a non-circular cross-section extending from the upper surface, and a hollow shaft extending from the lower surface, attaching to a syringe barrel.
BRIEF DESCRIPTION OF THE DRAWINGS
 The various features, objects, benefits, and advantages of the present invention
will become more apparent upon reading the following detailed description of the preferred embodiment(s) along with the appended claims in conjunction with the drawings, wherein like reference numerals identify like components throughout, and:
 FIG. 1 is a perspective view of a tip cap according to an embodiment of the
 FIG. 2 is a first side view of the tip cap of FIG. 1;
 FIG. 3 is a second side view of the tip cap of FIG. 1;
 FIG. 4 is top view of the tip cap of FIG. 1;
 FIGS. 4a and 4b are a cross-sectional views of the tip cap according to the
present invention along sections lines 4a-4a and 4b-4b of FIG. 4.
 FIG. 5 is bottom view of the tip cap of FIG. 1;
 FIGS. 6 and 6a respectively are perspective views of a tip cap according to
different embodiments of the present invention with a textured top wall;
 FIG. 7 is top view of the tip cap of FIG. 6;
 FIG. 8 is a force diagram for the rotation of a tip cap according to a prior art
 FIG. 9 is a force diagram for the rotation of a tip cap according to the present
 FIGS lOa-lOf are perspective views of various alternate embodiments of the
present invention incorporating gripping elements.
DETAILED DESCRIPTION OF THE INVENTION
 Referring now to the drawings, FIG. 1 shows a tip cap according to the present
invention. In particular, FIG.l shows a tip cap 10. As can be seen, tip cap 10 includes a cap body 12 having a top wall 14 and a depending sealing base 16, and further included a shaft 18 for connecting to and disconnecting from a syringe 200. The shaft 18 and the cap body 12 form a single unitary tip cap for receiving a force imparted to the top wall 14 which causes the tip cap 10 to rotate and connect to a syringe body. The top wall 14 is a non-circular tubular structure, extending upwardly from the sealing base 16. The sealing base 16 is a substantially flat surface having top 16a and bottom 16b faces respectively. Top wall 14 is rigidly joined to sealing base top 16a, preferably about at least the majority of its perimeter, and the shaft 18 is rigidly joined to sealing base bottom 16b.
 FIG. 2 depicts the tip cap 10 according to the present invention as viewed
from the side along a major axis 40 of the cap body 12. As seen in FIG. 2, the top wall 14 is preferably coextensive with the sealing base 16 along major axis 40 of the cap body 12. Also shown is the shaft 18 extending downwardly from the sealing base 16. The shaft 18 is configured to attach to the luer tip 220 of a syringe 200. A connector 230 may be provided at the tip 220 of the syringe 200 such as, for example, a luer locking collar. The connector 230 may include internally defined threads 232. Preferably, the shaft 18 has threads 20 for engaging complementary threads 232 of the connector 230 The threads 20 are arranged to provide adequate locking for a given angular displacement of the tip cap 10. With this arrangement a seal is defined about the luer tip 220 by tight contact with the interior of the
shaft 18. The threads 20 can be configured to cooperate with any known threaded configuration and provide additional holding force to maintain the position of the tip cap 10 relative to the luer tip 220. Alternatively, the shaft 18 may be configured with any other known connection configuration, including, but not limited to, a slip luer connection.
 FIG. 3 depicts the tip cap 10 according to the present invention as viewed
from the side along minor axis 42 of the tip cap body 12. Preferably, as seen in FIG. 3, portions 16c of the sealing base 16 extend radially outwardly along the minor axis 42 of the top wall 14. The portions 16c may act as shields against excessive downward movement of a user's fingers relative to the tip cap 10. With the portions 16c, inadvertent contact with an associated syringe body, particularly a portion that has been sterilized, can be avoided.
 FIG. 4 depicts the tip cap 10 according to the present invention as viewed
from the top. In this view, the substantially non-circularity of the top wall 14 is shown. Preferably, the top wall 14 is elongated, having the major axis 40 and the minor axis 42. The top wall 14, according to the present invention, will preferably be formed in a non-circular elliptical shape, thereby providing an elongated gripping surface 50 defined by the top wall 14. The gripping surface 50 (see, e.g., FIG. 2) need not be limited to the surface defined along the major axis 40, but can include the surface defined along the minor axis 42. In addition, the gripping surface 50 may include a surface that extends along both the major and minor axes 40,42. As will be described with reference to FIG. 9, the non-circular shaped top wall 14 allows a user to grasp the tip cap 10 and apply a rotational force (torque) to the tip cap 10, without having to simultaneously provide a tight grip on the tip cap 10. In addition, with the non-circular shaped top wall 14 of the present invention, the tip cap 10 is unable to roll away from a user, as is often the case with circularly shaped prior art tip caps.
 FIGS. 4a and 4b depict cross-sectional views of the tip cap according to the
present invention along sections lines 4a-4a and 4b-4b of FIG. 4. As shown in cross sections 4a-4a and 4b-4b, shaft 18 is preferably hollow having inner and outer walls 54 and 56, respectively and being open at the bottom end. Preferably, a well 58 is defined to at least partially extend through the sealing base 16 shaped and configured to receive a luer tip which would extend beyond the bottom face 16b with the tip cap 10 being mounted to the syringe 200, as depicted in FIG. 2. The well 58 may be shaped internally to match the general shape of the tip or luer. For example, as shown in FIG. 4a, the inner end 59 of well 58 has a flat profile, complementary to that of the part of the syringe to which it is secured. External surface 44 of the well 58 can be generally conical, as shown to advantageously be relied upon in releasing the product from a mold. Also shown are depressions 52 recessed into the bottom face 16b
 FIG. 5 depicts a bottom view of the tip cap 10 according to the present
invention. Shown in FIG. 5 is the bottom face 16b of sealing base 16. To facilitate removal of the tip cap 10 from a molding machine, one or more depressions 52 may be recessed into the sealing base 16, such as shown, recessed into the bottom face 16b.
 It should also be noted that one or more outwardly extending nubs or tabs 51
may be formed extending in cantilevered fashion from the edge of sealing base 16 to facilitate handling of the tip cap 10 according to the present invention by machinery. The nubs or tabs 51 allow machinery, such as "forgiving" machines to handle the tip cap 10 without engaging the gripping surface 50. Accordingly, a more straightforward machine arrangement to engage nubs or tabs 51, may be utilized than if the gripping surface 51 needed
to be handled. While four such nubs or tabs are shown in FIG. 5, it would be understood by one skilled in the art to modify the number and placement of such structures as needed.
 As shown in FIGS. 6, 6a and 7, the tip cap 10 may have a textured top wall 14.
For example, the tip cap 10 depicted in FIG. 6 includes a plurality of ribs 60 on the exterior of the top wall 14. The ribs 60 provide texture to the top wall 14 exterior surface in order to provide the user with an enhanced gripping surface. As will be apparent to one skilled in the art and from the disclosure provided herein, the placement and number of ribs can be varied to provide the user with the desired tactile sensation and grip characteristics. In addition, while the surface texture in this embodiment is shown as ribs, the surface of top wall 14 could alternately have other types of textures or exterior structures to provide tactile sensation and additional grip. As will be recognized by those skilled in the art, and shown in FIG. 6a, the top wall 14 could for example alternately have dimples or any other known texture, including, but not limited to, the textures found in a library maintained under the trademark "MOLD-TECH" by Standex International Corp. of Salem, New Hampshire, U.S.A..
[00371 Turning now to FIG. 7, the profile of ribs 60 can be seen. Preferably, ribs 60
are located on the exterior of top wall 14 along the longer wall portions (disposed along the major axis 40). In this way the ribs 60 are located where a user would grip the tip cap 10 in order to rotate the tip cap. In addition, the ribs 60 further provide a surface that would not cut into the fingers of the user. As seen in FIG. 7, the cross-sectional profile of the body 12 of the tip cap 10 is elliptical with a plurality of grooves 62 defined in the gripping surface 50. Thus, the elliptical gripping surface 50 is free of protrusions that would press into the users fingers under high torque on/off situations. Alternate texture could also be located in the same location as depicted in FIG. 7.
 Turning now to FIG. 8, there is shown a force diagram that illustrates the
application offerees by a user to rotate a prior art cap about its central axis. FIG. 8 shows a
circular top wall 80 of a prior art tip cap, having a central axis 82 and which is being grasped
by a user's hand 84. User's hand 84 is shown exerting a gripping force 86, normal to the
surface of the top wall 80. In order to rotate the cap the user must also apply a rotational
force (torque) to the tip cap. For example, to rotate the tip cap in a clockwise direction, the
user would apply force 88 tangential to the top wall 80. Likewise, to rotate the tip cap in a
counterclockwise direction, the user would apply force 89 tangential to the top wall 80 axis of
rotation. The amount of gripping force 86 the user must apply is proportional to the
rotational force needed to turn the tip cap. For example, a user must grip the tip cap more
tightly when turning a tip cap that has been tightly closed as opposed to a tip cap that has
been less tightly closed. '
 In FIG. 9, there is shown a force diagram depicting the application of force by
a user to rotate the tip cap 10 according to the present invention. FIG. 9 shows a top view of the tip cap 10 according to the present invention, depicting a non-circular top wall 14, having a central axis 90 and which is being grasped by a user's hand 92. To rotate the cap in a counter clockwise direction, the user would apply forces 94 to the top wall 14. Likewise, to rotate the tip cap in a clockwise direction, the user would apply forces 96 to the top wall 14. In contrast to prior art designs, the user of the tip cap 10 according to the present invention merely applies a rotational force to the tip cap 10 to threadedly engage or disengage the tip cap; but a large gripping force is not required.
 More particularly, a tip cap is opened or closed by imparting a force to the tip
cap sufficient to overcome the forces holding it in place on the helical threads of the cap and the complementary container, or other complementary connection configuration, whereby the cap is moved from either an open or a closed position by the rotation of the cap. The forces to rotate the threaded cap are applied tangential to the axis of rotation of the cap at a distance from the axis of rotation. As shown and described in FIG. 8, in order to rotate a prior art round cap, it must be grasped with sufficient force to hold the cap, as well as rotate the cap about its central axis. Thus, force must be applied tangential to the axis of rotation to rotate the cap and normal to the cap surface to grasp and hold the cap. The force applied to hold the cap, is proportional to the rotational force applied thus making the application of both a gripping and rotating force more difficult, especially, for example when rotating a cap that is tightly affixed.
 In contrast, the tip cap 10 according to the present invention, has an elongated
gripping portion that provides the user with a lever arm to easily rotate the tip cap 10. Preferably, as depicted in FIG. 9, the user grasps the tip cap 10 at any points 98 on the top wall 14 a distance "d" from the central axis 90 as measured along the major axis 40. The forces 94 or 96 is exerted directly on the top wall 14. The user need not grip the tip cap 10 to prevent slipping, because, unlike a round cap, the rotational forces (94 or 96) is exerted normal to the top wall 14 at the points 98. The top wall 14 acts as a lever arm of length "d" to provide mechanical advantage to rotate the tip cap 10.
 Rotational force may be used to remove the tip cap 10 even where a threaded
connector is not provided for a syringe body. For example, the tip cap 10 can be twisted off
of a luer onto which it is mounted with a slip luer connection. The torque advantage described above, therefore, is as beneficial in this context, and similar contexts, as well.
 The tip cap 10 of the invention may be made of a clear molded thermoplastic
material so that the syringe tip may be readily viewed through the tip cap. Representative materials include, for example, polyethylene, polypropylene, and polyvinyl chloride. Although it is within the purview of the invention to provide tip caps which are transparent, it is also within the purview of this invention to provide tip caps which are color coded for defining the kind of examination to be conducted on the specimen collected.
 While the tip cap 10 of the present invention has been particularly described
with respect to a preferred embodiment having a non-circularly elliptical shaped top wall 14, it should be apparent to one skilled in the art and from the disclosure provided herein that various alternate embodiments of the tip cap top wall 14 are contemplated by, and within the scope and spirit of the present invention. For example, the tip cap 10 may alternately include modifications such as alternate shapes or additional gripping elements to enhance torque generation. Alternate top wall 14 shapes can include, in addition to the non-circular elliptical shape of the preferred embodiment, oval shapes, polygonal shapes, such as squares and rectangles, and other non-circular shapes that provide the desired torque-reducing characteristics of the tip cap 10 of the present invention. Furthermore, additional alternate embodiments may include the tip cap top wall 14 having radially projecting structures arranged about the top wall 14. The projecting structures provide the user with an extended gripping surface 50, which acts as a lever arm to impart additional torque to the tip cap 10 when rotated by the user, as described above in connection with the embodiments of FIGS. 1-7 and 9.
 The gripping elements may alternately be arranged in such a way as to provide
.the user with an easily gripped surface for imparting torque to the tip cap 10. The gripping element may take various alternate forms, for example, the tip cap 10 may be made with a star shape or having radially extending structures arranged around the perimeter of the tip cap 10. Alternately, the tip cap 10 can be shaped having a square or rectangular shape.
 As will be recognized by one skilled in the art. various configuration can be
resorted to falling within the principles of the invention discussed above. By way of non-limiting examples and turning to FIGS. lOa-f, alternate embodiments of the tip cap 10 according to the present invention are shown. FIG. lOa depicts an alternate embodiment wherein flanges 104 are positioned adjacent top wall 14 to provide the user with an enlarged gripping element, wherein the flanges extend outwardly from the top wall in a radial direction to the edge of sealing base 16. It should be noted however, that the dimension and size of the flanges can be varied to provide the user with a surface of sufficient size to apply force to rotate the tip cap. Preferable, the flanges 104 each have a radial length extending outwardly greater that their respective width extending in a circumferential direction. Furthermore, additional flanges 104 could be utilized in a further variation of the embodiment depicted in FIG. lOa. In addition, ribs 102 may also be provided with the embodiment of FIG. lOa, for providing an additional gripping element. It should be noted that the radial distance from the center of the tip cap 10 to the edge of the flange 104 is greater than the radial distance to the edge of the rib 102.
 FIG. lOb depicts a further alternate embodiment having two arcuate structures
108 protruding from sealing base 16 being generally concave in shape. The arcuate
structures 108 are rigidly connected together by support 110 that also extends from sealing base 16. The structures 108 provide an easily gripped surface for the user to impart torque to the tip cap 10. As further seen in FIG. lOc, the shape and size of the arcuate structures 108 can be varied to, for example, increase the size of the gripping surface. It should be further noted that it would be apparent to one skilled in the art that the embodiments of FIGS. lOb and 1 Oc do not have a receptacle shaped cap gripping surface. For this reason these embodiments resist the retention of moisture during a steam autoclave process. In addition, they have the added advantage of not being subject to a proclivity to nest one inside another when stored in bulk.
 Turning now to FIG. lOd, a further alternate embodiment is depicted having a
central structure 112 extending from sealing base 16, with a plurality of structures 114 disposed about the central structure 112 at preferably ninety-degree intervals, for providing an easily gripped surface for the user to impart torque to the tip cap 10. FIG. lOd may be modified in accordance with the present invention by changing the number and spacing of outer structures 114, in addition while structures 112 and 114 are depicted as cylindrical, any other shape may be utilized, such as, for example, polygonal.
 FIG. lOe depicts a further alternate embodiment wherein the tip cap 14
according to the present invention has an increased diameter top wall 14 with an undulating wall cross-section to provide a plurality of ribs 120 circumferentially spaced about top wall 14 and interconnected by a rib webs 122 to provide the user with an enhanced gripping surface by varying the angle of the surface that the user grips. In that way, the user can hold a surface that is not tangential to the rotational axis of the tip cap 10.
1. A syringe assembly comprising:
a syringe (200) comprising a barrel, a syringe tip (220) extending from said barrel (200), and a connector (230) around the syringe tip; and
a tip cap (10) for sealingly covering said syringe tip (220) and comprising
a base portion (16) having an upper surface (16a) and a lower surface (16b), a body (12) having a top wall (14) extending from said upper surface, and a shaft (18) extending from said lower surface having connection means for attaching to said syringe tip (220), said connection means comprising threads (20) for engaging complementary threads (232) of the connector (230),
characterized in that
said top wall (14) has a non-circular cross-section comprising a major axis (40) and a minor axis (42), and, when said tip cap (10) is on said syringe (200), the portions of the top wall (14) lying on the major axis (40) protrude laterally beyond the connector (230) of the syringe.
2. The syringe assembly as claimed in claim 1, wherein said body (12) is a cylinder having an elliptical cross-section.
3. The syringe assembly as claimed in claim 1, wherein said body (12) is a cylinder having an oval cross-section.
. 4. The syringe assembly as claimed in claim 1, wherein said body (12) is a cylinder having a rectangular cross-section.
5. The syringe assembly as claimed in claim 1, wherein said non-circular section is comprised of a pair of arcuate structures (108).
6. The syringe assembly as claimed in claim 1, wherein said non-circular section is polygonal in shape.
7. The syringe assembly as claimed in claim 1, wherein said non-circular section is comprised of a plurality of cylindrical structures (114) arranged around the central axis of said tip cap.
8. The syringe assembly as claimed in claim 1, wherein said top wall (14) is at least partially
perimetrically disposed on said upper surface (16a).
9. The syringe assembly as claimed in claim 1, wherein the exterior of said body (12) includes a textured surface.
10. The syringe assembly as claimed in claim 9, wherein said textured surface includes a plurality of ribs (60).
11. The syringe assembly as claimed in claim 9, wherein said textured surface includes a plurality of dimples.
12. The syringe assembly as claimed in claim 9, wherein said textured surface includes a plurality
of radially extended flanges.
13. The syringe assembly as claimed in claim 1, wherein said connection means is a luer slip connection.
14. The syringe assembly as claimed in claim 1, wherein said connection means is a helical thread (20).
15. The syringe assembly as claimed in claim 1, wherein a recessed well (58) extends at least partially through said lower surface (16b) of said base portion (16).
16. The syringe assembly as claimed in claim 15, wherein said syringe tip (220) at least partially extends into said well (58) with said tip cap (10) covering said syringe tip of said syringe.
|Indian Patent Application Number||4721/DELNP/2005|
|PG Journal Number||37/2011|
|Date of Filing||17-Oct-2005|
|Name of Patentee||BECTON, DICKINSON AND COMPANY|
|Applicant Address||ONE BECTON DRIVE FRANKLIN LAKES NJ 07417 U.S.A.|
|PCT International Classification Number||A61M 5/31|
|PCT International Application Number||PCT/US2003/033484|
|PCT International Filing date||2003-10-22|