Collection assembly

The present invention is a collection assembly useful for collecting small quantities of blood. The assembly comprises a container with an integral lip for facilitating collection of the blood and a cap suitable for enclosing the container. The assembly further comprises a sealing arrangement for securing the cap with the container and a cam follower within the cap that interacts with the integral lip of the container to unsecure the cap from the container.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to a collection assembly and, more 
particularly, to a microcollection container and cap suitable for 
collecting small quantities of blood from a patient and maintaining the 
blood in secure fashion for subsequent testing. 
2. Description of Related Art 
Analytical instrumentation has made it possible to carry out a variety of 
hematological diagnostic procedures on very small quantities of blood. 
Because of this, a patient's finger or earlobe, for example, may be 
punctured and a very small quantity of blood may be rapidly collected into 
a container for such testing. However, in order to carry out testing and 
analysis on small quantities of blood, the blood must be rapidly collected 
prior to any coagulation thereof. 
A collection arrangement as described in U.S. Pat. No. 5,288,466, has been 
provided wherein a cap having a sealing element is configured to fit the 
top of a microcollection container having a lip for engaging the puncture 
site and transferring blood to the container. However, with such an 
arrangement, when a sample is taken, blood droplets may be left in and 
around the top area of the container or on the bottom of the sealing 
element. Therefore, excess blood may be aspirated when the cap is removed 
from the top of the container. 
SUMMARY OF THE INVENTION 
The present invention is a collection assembly comprising a container and a 
cap. The cap preferably comprises a closed top portion, an open bottom 
portion, and an annular skirt extending from the top portion to the bottom 
portion having an inner surface and an outer surface. The cap further 
includes an inner inverted skirt portion having a sealing ring at its 
extremity that is surrounded by the inner surface of the annular skirt. 
Most preferably the inner inverted skirt portion is separated from the 
inner surface of the annular skirt by an annular space, with the cap 
including a cam follower positioned on the top portion. Desirably, the 
inside surface of the annular skirt comprises at least one protrusion and 
the inner inverted skirt portion has a sealing ring. The cap further 
comprises a shield extending from the outer surface of the annular skirt 
at its open end. 
The container preferably comprises an open top portion, a closed bottom 
portion, a sidewall extending from the top portion to the bottom portion 
and an open end associated with the top portion having an integral 
collector or lip portion. Most preferably the integral collector is a 
scoop that is the same diameter as the inner diameter of the container so 
that no air vent is required. 
Preferably, the container further includes a cap seating flange associated 
with the outer diameter of the top portion of the container and an 
extending annular skirt associated with the bottom portion. Most 
preferably, a blood trap or trough is positioned within the cap seating 
flange and a locking ring is associated between the integral collector and 
the cap seating flange. 
Preferably, the collection assembly includes means for securing the inner 
surfaces of the cap to the top portion of the container by the interaction 
of the protrusions of the cap with the locking ring of the container and 
the sealing ring of the cap with the inside surface of the top portion of 
the container. Most preferably, the collection assembly also includes 
means for unsecuring the cap from the container by a cam arrangement on 
the cap and container. This cam arrangement assists in substantially 
reducing fluid splatter from the container when the cap is removed from 
the container. 
In a preferred embodiment of the invention, the cam arrangement includes at 
least one cam follower positioned on the top portion of the cap and a pair 
of cam surfaces on the integral lip of the container. A downward 
rotational force applied to the cap and an upward force applied to the 
container along the longitudinal axis, causes the cam follower and a cam 
surface to align and the cap to snap-seal to the container by the 
interaction of the protrusions of the cap with the locking ring of the 
container and the sealing ring of the cap with the inside surface of the 
top portion of the container. This action, which may cause an 
audible-snap, in turn seals the container by compressing the protrusions 
of the cap against the locking ring of the container and the sealing ring 
of the cap against the inside surface of the top portion of the container 
to form a non-permanent lock and to substantially prevent the outer 
surface of the top portion of the container from making contact with the 
inside surface of the cap's annular skirt. 
The cap and container are then unsecured in a twist off manner by applying 
a rotational force to the cap. Most preferably, an upward rotational force 
is applied to the cap and a downward force is applied to the container 
along the longitudinal axis. This causes the cam follower to rise on one 
of the cam surfaces and in turn the cap is unsecured from the container. 
An important advantage of the present invention is that the rotational 
force applied to the cap can be bi-directional, that is clockwise or 
counter-clockwise. 
An advantage of the present invention is that any excess fluid on the 
outside surface of the integral collector is directed downward into the 
blood trap or trough of the cap seating flange when a downward force is 
applied to the cap as the cap and container are being secured. Therefore, 
radial spray of excess fluid is minimized. 
Still another advantage of the invention is that the recessed inverted 
skirt and the sealing-ring substantially reduce cap contact with fluid 
collected in the container. Therefore the inner surfaces of the cap may be 
minimally exposed to fluid collected in the container when the cap is 
secured to the top portion of the container and again radial spray of 
excess fluid is minimized during cap removal. 
Another advantage of the present invention is that the outer surface of the 
cap may preferably be configured to substantially limit movement or 
rolling of the cap or the assembly. This applies whether the cap is 
positioned within the top portion or bottom portion of the container. 
Another advantage of the present invention is that when the cap is secured 
to the container, the rim of the cap substantially prevents contamination 
to the specimen inside the container. In addition, when the cap is secured 
to the container the flange on the container is not covered completely by 
the shield on the cap, so that when the capped assembly is centrifuged the 
load is on the flange and the cap is not loosened.

DETAILED DESCRIPTION 
Referring to the drawings in which like reference characters refer to like 
parts throughout the several views thereof, FIG. 1 illustrates a 
collection assembly 10 comprising a container 12 and a cap 14. 
As illustrated in FIG. 1, container 12 has a sidewall 22 having an outer 
surface 24 and an inner surface 26. Sidewall 22 extends from an upper 
portion 28 to a lower portion 30. Upper portion 28 includes an open end 31 
and an inner surface 27 with a top surface 32 having an integral lip 
portion 34 with a receiving edge 36 and a pair of cam surfaces 46. Lower 
portion 30 comprises a closed bottom end 38 and an annular skirt 37 
extending from closed bottom end 38 to define a compartment area 39. 
Annular skirt 37 provides a means for allowing the container to be placed 
upright on a flat surface and means for receiving cap 14. 
Upper portion 28 has a cap seating flange 40 positioned around outer 
surface 24 of container 12 which defines a well or trough 42 having an 
outer wall 41 with an upper surface edge 43. Further positioned on upper 
portion 28 of container 12 is a locking ring 48 that is positioned between 
receiving edge 36 of integral lip portion 34 and cap seating flange 40. 
Locking ring 48 has an upper edge 50 and a lower edge 52. 
Cap 14 as shown in FIG. 2, has a top surface 54, a bottom stop ledge 56 and 
an annular outer skirt 58 extending from top surface 54 to bottom stop 
ledge 56. Annular outer skirt 58 has an outer wall surface 60 and an inner 
wall surface 62, and a shield 66 extends from the bottom of outer wall 
surface 60 of annular outer skirt 58 and has an outer surface or 
circumference 76. 
As shown in FIG. 2, cap 14 also has an inner annular inverted recessed 
skirt 64 that extends from top portion 54 to a bottom surface 63. Inverted 
recessed skirt 64 defines a compartment or cup area 65 in top portion 54 
of cap 14. Inner wall surface 62 of annular outer skirt 58 and inner 
annular inverted recessed skirt 64 are spaced from each other to define an 
annular space 68. The cap further includes, a plurality of 
circumferentially spaced protrusions 70 positioned on inner wall surface 
62 and a sealing ring 67 positioned on inverted recessed skirt 64. A cam 
follower surface 74 extends from top portion 54 of cap 14 into annular 
space 68, as shown in FIGS. 2 and 3. 
As shown in FIG. 4, flats 77 are positioned on outer surface 76 of shield 
66. Flats 77 substantially prevent cap 14 from rolling and provide a 
convenient grasping surface for ready removal and placement of cap 14 on 
container 12. Although a shield with a smooth outer circumference without 
flats is within the purview of the instant invention, a shield with an 
outer surface with flats is preferred. 
As shown in FIG. 5, when cap 14 is removably secured to container 12, space 
68 of cap 14 receives upper portion 28 of container 12 including integral 
lip portion 34, protrusions 70 bear against lower edge 52 of locking ring 
48 of container 12, sealing ring 67 bears against inner surface 27 of 
container 12 and cam follower 74 contacts top surface 32 on open end 31. 
Shield 66 covers outer wall 41 of cap seating flange 40 and bottom stop 
ledge 56 abuts with upper surface edge 43 of cap seating flange 40, so as 
to form a non-permanent lock and substantially prevent any excess fluid in 
well 42 of cap seating flange 40 from spilling out. Any fluid that 
migrates between upper surface edge 43 and bottom stop ledge 56 is 
directed in a downward direction along the container by an inner surface 
81 of shield 66. In addition, spaces 82 and 83 remain between integral lip 
portion 34 and each skirt 58 and 64 to prevent blood on lip portion 34 
being pushed down towards bottom stop ledge 56. Further, any fluid in well 
42 is substantially contained by upper surface edge 43 of cap seating 
flange 40, bottom stop ledge 56 of cap 14 and inner surface 81 of shield 
66. Outer surface 76 of shield 66 does not cover cap seating flange 40 of 
container 12 completely, as shown in FIG. 5, so that when the capped 
assembly is centrifuged the load is on flange 40 and cap 14 is not 
loosened. 
Cam follower surface 74 and upper portion 28 are configured so that a 
downward rotational force applied to cap 14 about longitudinal axis 80 
causes cam follower 74 to contact top surface 32. Preferably, cam follower 
surface 74 has a triangular shape, however, any shape that can easily 
follow top surface 32 and cause cap 14 to separate from container 12 is 
acceptable. Cap 14 is snapped onto upper portion 28 of container 12 as 
guided by cam follower surface 74 and top surface 32. Cap 14 is removably 
secured to container 12 by protrusions 70 and sealing ring 67 as they bear 
respectfully against lower edge 52 of locking ring 48 and inner surface 27 
of container 12. The position of protrusions 70 and sealing ring 67 of cap 
14 with container 12 forms space 69 between outer surface 24 of upper 
portion 28 and inner wall surface 62 of annular outer skirt 58. Therefore, 
wiping down of any fluid on the container's outer surface is substantially 
prevented. In addition, bottom stop edge 56 bears against flange upper 
surface 43 to provide a stop and insure proper sealing depth for sealing 
ring 67 on container upper inner surface 27. 
Cap 14 is unsecured from the container in a twist-off manner by applying a 
rotational force about longitudinal axis 80 while holding container 12. 
Rotation of cap 14 with respect to container 12 causes cam follower 
surface 74 to follow top surface 32 on upper portion 28 to the base of one 
of two cam surfaces 46, as shown in FIG. 6. As the cap 14 is rotated 
further, cam follower surface 74 rises on one of the cam surfaces 46 and 
in turn cap 14 is unsecured from container 12, as shown in FIG. 7. The 
rotational force applied to cap 14 can be bi-directional, that is 
clockwise or counter-clockwise. 
The collection assembly of the invention may be made of a molded 
thermoplastic material so that the specimen collected may be readily 
viewed. Representative materials include, for example, polyethylene, 
polypropylene and polyvinyl chloride. The collection container may 
incorporate a hydrophilic material or a silicon, or a texture may be 
applied to the internal surface thereof for enhancing the flow and mixing 
of blood introduced into the container. 
Although it is within the purview of the invention to provide caps which 
are colored to define specific forms of fluid collection containers 
containing materials for one reason or another or for defining the kind of 
examination to be conducted on the specimen collected, transparent caps 
may be provided. Also, it should be noted that the dimensions of the 
container are such as to provide space for labeling which may be important 
for identifying the collected specimens.