Blood Evacuating System and Method of Use Thereof
TECHNICAL FIELD
The present invention relates generally to an apparatus and method for collecting fluids and the reinfusion of the fluids to a patient, and particularly to a blood evacuation system adapted for autotransfusion. More specifically, the present invention is directed to a blood evacuation system that permits a disposable inner evacuation bag to be separated from an outer container for reinfusion so that another evacuation bag may be inserted inside the container to continue blood evacuation.
BACKGROUND ART
Blood evacuating apparatuses are commonly used in autotransfusion to evacuate and collect autologous blood from the collection chamber of a chest drainage unit.
Autotransfusion refers to the reinfusion of a patient's own blood, known as autologous blood. Autotransfusion is the preferred method of reinfused since the blood being transfused is the patient's own blood, therefore eliminating problems over blood type incompatibility and exposure to blood carrying diseases such as hepatitis, AIDS, etc. Moreover, autologous blood is more fresh than stored blood supplied by a donor and also contains the patient's own antibodies . One type of autotransfusion, referred to as "postoperative" autotransfusion, is the transfusion of the patient's own shed blood following surgery where drained
blood is collected and reinfused into the patient. Postoperative autotransfusion is limited m use since there are strict guidelines for the kind of blood which can be reinfused. Currently, the only post -operative blood believed suitable for autotransfusion is mediastmal blood, i.e. the blood which comes from the anatomical space or cavity m the chest .
Presently, chest drainage units are commonly used m the post -operative care of patients having surgery involving the chest cavity. Chest drainage units remove fluids and air from inside the chest cavity using tubing connected to the patient's chest cavity which drains the fluid and air into a collection chamber of the chest drainage unit. The chest drainage unit is attached to a source of vacuum which applies a suction to the tubing and draws the trapped fluid and air from the chest cavity and into the collection chamber. Once collected, the blood may be evacuated from the collection chamber using an autotransfusion pump or blood evacuation bag. The use of a blood evacuation bag m autotransfusion is well known m the art. For example, U.S. Patent No. 5,380,314 to Herweck et al . discloses a blood collection bag having an internal spring that resiliently biases the bag into a fixed shape prior to use while concurrently inducing a negative pressure therein m order to manually draw blood from the collection chamber of the chest drainage unit. However, one disadvantage with the '314 apparatus is that reinfusion must be accomplished using gravity means, whereby the bag is suspended m the vicinity of the patient and
gravity is allowed to drain the collected blood from the bag for reinfusion to the patient. Unfortunately, the '314 apparatus will not properly drain unless the user first takes the extra step of bleeding m ambient air into the blood collection bag prior to reinfusion. This bleeding step is necessary m order to force collected blood inside the rigid blood collection bag to drain, otherwise the force of gravity alone will prove insufficient to draw blood from the bag during reinfusion. Another example of a blood evacuation system is found m U.S. Patent No.5, 201, 703 to Gentelia et al . which discloses an apparatus for collecting blood from a chest drainage unit and reinfusion of the blood to the patient. The '703 patent is directed to a self-contained, totally disposable apparatus comprising an rigid outer container housing an integrally attached flexible bag for use with a chest drainage unit. Negative pressure is applied or maintained inside the interstitial space between the rigid container and the inner flexible bag for causing blood stored m the collection chamber to be drawn into the bag. As drawn blood travels through tubing connecting the 703 apparatus to the chest drainage unit, it begins to fill the flexible inner bag. Once the bag is filled to a desired level with blood the entire apparatus, including the outer rigid container and the blood-filled inner bag, are disconnected from the chest drainage unit and suspended from a suitable suspension means m the vicinity of a patient fo reinfusion of the collected blood.
However, a disadvantage with the '703 apparatus is that the entire apparatus must be employed during reinfusion. Specifically, both the outer rigid container and the inner flexible bag are utilized during the reinfusion process since the λ 703 apparatus has a unitary design wherein the inner flexible bag cannot be separated from the outer rigid container. As a result, another entire apparatus - a container and evacuation bag - must replace the used apparatus in order to continue the autotransfusion procedure on the same patient. Accordingly, the cost to the user is higher since the entire apparatus must be replaced after each transfusion.
Another disadvantage to the 703 apparatus is that the conventional means for attaining higher rates of reinfusion with the above noted blood evacuation systems are sometimes not possible. A prior art blood evacuation bag that fixedly attaches the evacuation bag to the outer rigid container or is made of a unitary, rigid container design are not adapted to employ high reinfusion rate techniques. For example, it is well known in the art that pressure cuffs wrapped around a flexible blood evacuation bag can generate higher reinfusion rates by applying pressure to a bladder of the pressure cuff surrounding the container. However, if the evacuation container is of a rigid design a pressure cuff surrounding the container is unable to exert sufficient pressure to collapse the inner flexible bag and generate a higher rate of reinfusion. In view of these disadvantages regarding cost and performance, it is desirable to have a blood evacuation system in which only the inner flexible bag
is used to re nfuse blood while the rigid outer container remains connected to a vacuum source for further collection of blood from the chest drainage unit .
Accordingly, a need exists m the art for a blood evacuation system that permits detachment of the inner flexible bag from the outer rigid container before reinfusion so that another flexible bag may be used inside the same container m order to collect further blood from the collection chamber. Moreover, there also exists a need m the art for a blood evacuation system that provides a cost effective means of remfusmg blood to a patient using multiple, detachable evacuation bags to continue blood evacuation while reinfusion takes place.
DISCLOSURE OF INVENTION A principle object of the present invention is to provide a cost-effective means of remfusmg blood to a patient .
Another object of the present invention is to provide an efficient method of remfusmg autologous blood to a patient.
A further ob ect of the present invention is to provide a blood evacuation system that includes an inner flexible bag that is separable from its outer container during reinfusion. Another further object of the present invention is to provide a separable evacuation bag that is adapted to receive a pressure cuff for generating a higher rate of reinfusion.
These and other objects of the present invention are realized in a presently preferred embodiment thereof, described by way of example and not by way of limitation, which provides for an apparatus and related method for evacuating and reinfusing blood to a patient using a blood evacuation system comprising a separable, flexible inner bag inside an outer rigid container for reinfusing shed blood drawn from the collection chamber of a chest drainage unit. 'The outer rigid container includes a suction port connected to a source of vacuum for applying a negative pressure within the interstitial space between rigid container and the inner flexible bag disposed therein. The negative pressure maintained within the interstitial space inside the container causes blood to be drawn into the bag from the collection chamber of the chest drainage unit through tubing which maintains fluid flow communication between the bag and the collection chamber. Once the bag is filled to a desired level, the inner flexible bag is removed from the outer rigid container and suspended within the vicinity of a patient for reinfusion of the collected blood.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a simplified block diagram showing the blood evacuation system according to the present invention; FIG. 2 is a perspective view of the rigid outer container and transfer tubing according to the present invention;
FIG. 3 is a partial cross section view of the rigid outer container showing the blood evacuation bag according to the present invention; and
FIG. 4 is a perspective view of the blood evacuation bag according to the present invention.
MODE(S) FOR CARRYING OUT THE INVENTION
Referring to FIG. 1, a simplified block diagram of an autotransfusion system 11 is illustrated showing the constituent elements of system 11. The autotransfusion system 11 comprises a patient 10 in fluid flow communication with a drainage device 12 using transfer tubing 24 to maintain fluid flow therebetween m direction A. The autotransfusion system 11 further includes a blood evacuation system 14 according to the present invention that is in fluid flow communication with the drainage device 12 using the same type of transfer tubing 24 used between the patient 10 and the device 12. Preferably, the transfer tubing 24 is made of a flexible plastic material, although any flexible material suitable for transporting fluid, such as blood, is felt to fall within the scope of the present invention.
Referring to FIGS. 2 and 3, the blood evacuation system 14 according to the present invention is shown. The blood evacuation system 14 comprises a rigid canister 16 with a flexible blood evacuation bag 38 disposed therein.
Preferably, the canister 16 has a generally round shape, although any shaped container suitable for storing fluid is felt to fall within the scope of the present invention. The canister 16 includes a lid 18 that is attached to a canister
body 21 by hinges 34 which permits the lid 18 to swing freely about the hinges 34 when opening and closing the canister 16. The canister 16 also includes a labeling area 20 on the outer surface. Preferably, the labeling area 20 includes a surface area for displaying instructions on the use of the blood evacuation system 14 for the user. The lid 18 of canister 16 has a dome-like shape with a suction port 32 in communication with the interior space 46 inside the canister 16. The lid 18 further includes a tubing groove 22 along the rim of lid 18 and a spike cover nest 28 formed in the middle of lid 18 for storing a spike cover (not shown) therein. The tubing groove 22 provides an opening whereby the transfer tubing 24 attached to the blood evacuation bag 38 is inserted therethrough and connected to the blood evacuation bag 38 to establish fluid flow communication with the collection chamber of drainage device 12. Although the tubing groove 22 does not maintain a hermetic seal inside the canister 16, sufficient negative pressure is maintained inside the interstitial space 50 between the canister 16 and the blood evacuation bag 28 to generate enough negative pressure inside the bag 28 for drawing blood into the blood evacuation bag 38.
The blood evacuation bag 38 disposed inside the canister 16 has a plurality of ports located at the top portion of the bag 38. One port, a reinfusion port 42, is closed and covered with a cap 52 and provides a site for draining collected blood from the blood evacuation bag 38 after the bag 38 is separated from the canister 16 during the reinfusion procedure. Another port, a collection port
40, is provided for attachment to the transfer tubing 24 leading from the drainage device 12 for the evacuation of blood therefrom.
Referring to FIG. 4, the blood evacuation bag 38 shall be discussed in greater detail. The blood evacuation bag 38 includes an expandable interior space 46 used for the evacuation of shed blood from the drainage device 12. As shed blood is collected inside the interior space 46 of the blood evacuation bag 38, the space 46 expands until the bag 38 is filled to the desired level. A hole 44 located at the bottom portion of the blood evacuation bag 38 below the interior space 46 serves as a site for suspending the bag 38 from a suitable suspension means (not shown) during reinfusion. A clamp 30 is also provided to prevent fluid flow through the transfer tubing 24 when the user wishes to stop the flow of blood into the blood evacuation bag 38 and to also prevent fluid flow from the bag 38 prior to reinfusion. Preferably, the blood evacuation bag 38 according to the present invention may be manufactured from any clear, flexible plastic material, although any material suitable for collecting and reinfusing fluid, like blood, is felt to fall within the scope of the present invention.
In establishing fluid flow communication between the blood evacuation bag 38 and the drainage device 12, a user engages a spike port (not shown) leading from the collection chamber of the drainage device 12 with a blood spike 26. The blood spike 26 is attached to a spike port (not shown) attached to the distal end of the transfer tubing 24 leading from the blood evacuation bag 38. Prior to engaging the
spike port, a dust cover 56 that caps the blood spike 26 during storage and transportation after manufacture is removed. Once the user engages the blood spike 26 to the spike port, a source of vacuum is applied to the suction port 32. When vacuum is applied to the inside of canister 16, negative pressure builds mside the interstitial space 50 between the inner surface of canister 16 and the outside surface of blood evacuation bag 38 mside the canister 16. With sufficient pressure decrease, blood collected mside the drainage device 12 flows through the transfer tubing 24 and fills the interior space 46 of the blood evacuation bag 38.
Once the blood evacuation bag 38 is filled to a desired level reinfusion of the blood may take place. The reinfusion procedure begins by the user applying the clamp 30 to the transfer tubing 24 and turning off the source of vacuum to the canister 16, thereby preventing fluid flow therethrough from the drainage device 12. After the transfer tubing 24 is clamped, the blood spike 26 is disengaged from the spike port and properly encapsulated using a spike cover (not shown) stored mside the nest 28 of the canister 16 to protect the contaminated pointed end 31 of the spike 26 after use. After encapsulating the blood spike 26, the lid 18 is opened and the blood evacuation bag 38 is removed from the canister 16 and suspended the vicinity of the patient using suitable suspension means, for example an IV pole. Once suspended, the user establishes fluid flow communication between the patient and the blood evacuation bag 38 by removing the cap 48 from the reinfusion port 42
and connecting transfer tubing 24 between the patient and the port 42.
Reinfusion may occur by one of several methods. Preferably, the blood evacuation bag 38 is suspended above the patient and the shed blood allowed to dram from the bag 38 using the force of gravity alone to draw the blood through transfer tubing 24 and into patient 10. An alternative method of reinfusion is to apply a pressure cuff (not shown) around the blood evacuation bag 38 as it is suspended. As the user applies pressure through a bladder of the pressure cuff, blood mside the blood evacuation bag 38 is forced out and a higher rate of reinfusion is attained due to the increased pressure. Preferably, a suspension means 19 is provided on the outer surface of canister body 21 and includes a hook integrally formed at the top portion for suspending the blood evacuation system 14. Alternatively, a VELCRO support and corresponding VELCRO loop can be provided at the bottom portion of canister body 21 for suspending the blood evacuation bag 38 from a suitable suspension means.
While reinfusion is occurring, the user may continue evacuating blood from the drainage device 12 by inserting another blood evacuation bag 38 into the canister 16 and reestablishing fluid flow communication between the bag 38 and the drainage device 12 as noted above. In this manner, "batch" autotransfusion takes place by simply replacing the blood evacuation bag 38 side the canister 16 every time a bag 38 is removed for reinfusion.
It should be understood from the foregoing that, while particular embodiments of the invention have been illustrated and described, various modifications can be made thereto without departing from the spirit and scope of the invention. Therefore, it is not intended that the invention be limited by the specification; instead, the scope of the present invention is intended to be limited only by the appended claims.