Two component syringe delivery system

A fluid delivery system where two reactive fluids are delivered simultaneously and separately from a pair of syringes to a delivery site. In one embodiment, a length of tubing exits one syringe and passes through a cannula exiting from the other syringe, to deliver both fluids, separately, but in a controlled volume and space to the delivery site. Alternately, the fluids can mix within the cannula, but its configuration prevents clogging at the delivery site.

FIELD OF THE INVENTION 
This invention relates to a system for delivery of two separate components. 
More specifically, this invention relates to a system for delivery of two 
separate components by syringe, where the components are mixed at the site 
of delivery. Most specifically, this invention relates to the delivery of 
two components by syringe where the components are mixed at the site of 
delivery and the components are delivered along generally equivalent path 
lengths. 
BACKGROUND OF THE INVENTION 
In the medical field, it may be desired to deliver two separate components 
to an active medical site. For instance, in the production of fibrin glue, 
it is desirable to deliver thrombin and fibrinogen to the same delivery 
site. As with the case in the formation of fibrin glue, it may be 
desirable to deliver the two components simultaneously and separately so 
that they only mix at the delivery site. For instance, with fibrin glue 
formation, if the components are delivered and mixed within a delivery 
system and then delivered to the delivery site, it is possible to clog the 
delivery system due to the adhesive nature of fibrin glue. On the other 
hand, other systems may need mixing at some point within the delivery 
tube. Of course, clogging of this tube is undesirable. 
Previous attempts at mixing the separate chemicals in a delivery system at 
the delivery site have met with little success. Therefore, common delivery 
systems may contain the improper mixture ratio of components, or have 
components mixed within the delivery system and then delivered, albeit 
over a short path length, to the delivery site. Devices which have 
attempted simultaneous delivery have been lacking in mechanisms for proper 
attachment of the delivery tubes. When these tubes clog, forces may cause 
the delivery tubes to separate from the syringe. Furthermore, systems 
where mixture is made at the delivery site are very difficult to 
manipulate. Frequent clearing of clogged components is necessary. 
Certainly, these present systems have all been virtually impossible to 
operate with one hand. 
Finally, none of the typical two component delivery systems, regardless of 
the location of the mixture of the two components, have been capable of 
operating with typical hypodermic syringes locked in place within a 
sturdy, lightweight, and functional locking mechanism that ensures 
simultaneous delivery of both separate components in the delivery system. 
The two component delivery systems have been either too bulky to deliver 
the two components adequately, or too flimsy to hold the typical 
hypodermic syringes. Because these systems operate with one hand, they are 
hard to formulate within a convenient package. 
SUMMARY OF THE INVENTION 
Therefore, it is an object of the invention to provide a two component 
delivery system where the components are delivered at the delivery site 
simultaneously and separately. 
It is further an object of the invention to provide a two component 
delivery system where the components are delivered separately and 
simultaneously to the delivery site along a single cannula. 
Another object of the invention is to provide a delivery system which 
prevents clogging of mixed fluids by having the fluids come into contact 
near the exit port and toward the delivery site. 
It is further an object of the invention to provide a two component syringe 
delivery system where the single cannula of the invention i adaptable for 
use with two typical hypodermic syringes. 
It is yet another object of the invention to provide a two component 
syringe delivery system where the syringes in the system can be managed 
and held in place securely by a holder which allows for simultaneous 
delivery of the two components through equivalent pressures on the two 
syringes. 
It is a final object of the invention to provide a two component syringe 
delivery system in which clogging is prevented along the entire length of 
the fluid paths of both components by preventing mixture of the two 
components until both components have exited the system, so that mixture 
is obtained at the delivery site. 
These and other objects of the invention are accomplished in a system 
whereby two typical hypodermic syringes can be locked in place within a 
syringe holder to provide uniform delivery of the two components. The 
syringe holder is formed such that the syringes are insertable through the 
holder itself and then locked in place along a channeled upper surface to 
prevent movement of either syringe. In addition, a plunger clip is 
inserted over the plungers of the syringes so that pressure can be equally 
distributed to both syringes during operation of the system. 
The locked syringes are then attached via luer lock fittings to a double 
tubing system. The tubes are attached so that they both reach the delivery 
site along roughly equivalent path lengths, so that the mixture of the two 
components can be made at the delivery site. 
Alternately, the two components are delivered into an assembled luer 
attachment which comprises a double luer (or luer lock) fitting attachable 
to both syringes. Within the syringes, there is described a double fluid 
path so that the fluids run parallel to each other at the exit of the luer 
attachment. At the attachment exit, there is insertable a single cannula. 
Projecting from the attachment is a length of tubing containing one of the 
elements. This tubing fits within the cannula so that one element travels 
the length of the cannula without contacting the cannula, down the length 
of the tubing. The other element exits the attachment and is forced around 
the tubing through the length of the cannula. The elements mix at or near 
the exit from the cannula, the first element exiting through the tubing 
and the second element exiting from the cannula and around the tubing. 
Again, the elements mix at or near the delivery site, and any reactive 
material is easily ejected from the large diameter cannula. 
The invention described in this summary will be better understood by 
reference to the attached figures and the detailed description cf the 
invention.

DETAILED DESCRIPTION OF THE INVENTION 
As seen in FIGS. 1-5, the two component syringe delivery system has as its 
basis two separate syringes 10, 20 for delivery of separate components. 
For instance, in one syringe there may be fibrinogen, and in an alternate 
syringe there may be thrombin. The combination will be mixed together at 
the delivery site for the formation of fibrin glue. 
The first component of the delivery system to be discussed is the holding 
mechanism 100 which assures proper delivery of the two components 
simultaneously. In the present holder 100, there are located bored holes 
105a, 105b and 106a, 106b, for both syringes and two sets of flanges 110, 
120 for locking, separated by arm 115. The lower set of flanges 120a, 
120b, keep the syringes 10, 20 in place from rotating around the upper set 
of flanges 110a, 110b. The upper flanges 110a, 110b ensure that the two 
syringes 10, 20 remain in desired position. 
Located in the upper flanges 110a, 110b are channels 130a, 130b which form 
a locking mechanism for the syringes. On the syringes 10, 20 there are 
ears 12a, 12b and 22a, 22b, which are usually gripped during individual 
operation of the syringes. These ears 12a, 12b, 22a, 22b, can be 
incorporated into channels 130a, 130b by first inserting the syringes 10, 
20 into the sets of holes 105, 106 and then rotating the ears of the 
syringes into channels 130a, 130b, as with locked syringe 20 in FIG. 1. 
When locked in place, both syringes 10, 20 are fixed in parallel or at an 
angle and can be given the appropriate amount of pressure to deliver 
simultaneously the two components of the system. When angled, the syringes 
10, 20 provide uniform mixing of the two components and can be used in a 
spray which mixes either at or near the delivery site. Simultaneous 
delivery is accomplished by the placement of plunger clip 140 at the 
plunger heads 15, 25 of the two syringes 10, 20. It is to be noticed that 
the clip 140 itself has channeled grooves 142, 144 which fit along the 
outer diameters of the heads 15, 25 of the two syringes 10, 20, so that 
the heads 15, 25 are positioned at the desired angle along the entire 
fluid paths. Heads 15, 25 are able to move within the clip 140 so that 
depression of both syringes 10, 20 is accomplished simultaneously. 
Thus, the user grasps the syringes with the thumb crossing the length of 
cap 140, the palm bridging the length of syringes 10, 20 and the index and 
third finger holding the holder 100 across the flanges 110a, 110b. By 
forcing the thumb on the cap 140, equivalent pressures are provided to 
both syringes 10, 20, and equivalent amounts of fluid are delivered from 
both syringes 10, 20. 
As further seen in FIG. 2, exiting syringes 10, 20 there are luer lock 
fittings 38, 48 which can be attached to the luer lock hubs 18, 28 of both 
syringes 10, 20. These luer lock fittings 38, 48 are attached at their 
opposite ends to flexible vinyl tubing 35, 45 forming a double cannula. 
Flexible tubing allows rotation of the luer lock fittings 38, 48 This 
double cannula is joined so that the dual cannula tubings 35, 45 are 
attached at the ends, usually with solvent adhesive. Thus, when the 
equivalent amounts of pressure are provided, the dual cannula 35, 45 is 
able to deliver the same amount of fluid from each syringe 10, 20. These 
cannulas will generally have outer diameters of about 0.060" and inner 
diameters of about 0.020", with lengths anywhere from 1" to 5". Because 
the tubings 35, 45 are cut off at equivalent lengths, there is 
simultaneous delivery of fluid from both syringes. 
Alternately, a single cannula solution is found in FIGS. 3-5. There is 
shown connector 200 which has a double luer fitting 208, 218. This fitting 
208, 218 may be a general or luer lock fitting. This connector 200 
contains hollowed double fluid path 209, 219 which is formed from tubing 
or plastic molding. At the end of the double fluid path 209, 219 there is 
luer hub 220. Attached through luer hub 220 is fluid path 219, which 
allows the fluid from syringe 20 to flow directly through the hub 220. 
Fluid in first path 209 is deposited into hub 220. Thus, the central 
portion of hub 220 can be filled with fluid from syringe 10. 
Single cannula fitting 240 has a cannula 242 extending from it so that 
cannula 242 would allow approximately twice the volume of fluid as 
compared to fluid path 219. When single cannula 240 is fit within the luer 
hub 220, therefore, equivalent volumes of the fluid from syringe 10 travel 
the length of the cannula 242 half filled with fluid path 219, with 
equivalent volumes of the fluid from syringe 20 flowing through the fluid 
path 219. Again, equivalent volumes of both fluids reach the end of the 
cannula 242 simultaneously Mixing can take place outside the cannula 242 
sr that clogging is prevented along the cannula 242. 
In addition, fluid path 219 may end at some point near the end of cannula 
242, so that mixing occurs just before the delivery site. Reacted 
materials are easily ejected from cannula 242 since its diameter is larger 
than either of paths 209, 219. 
Thus, with the two component delivery system, equivalent pressures are 
derived and these equivalent pressures are able to provide for equivalent 
amounts of fluid flowing the length cf the system. When the equivalent 
amounts of fluid are ejected from the system, they are able to mix at the 
delivery site so that clogging is prevented in the system. In addition, 
chemical reactions can take place outside the cannula, or pre-mix before 
delivery without clogging as desired. Finally, the entire system is able 
to Provide the proper amounts of fluid directly to the delivery site. 
These and other objects of the present invention are to be determined from 
the attached claims and their equivalents.