Medicinal fluids or solutions intended for patient administration are frequently provided in an inverted bag having a septum or other access port capable of being pierced on the bottom of the bag. A sharp hollow spike attached to a tubing set may be introduced through the septum, thus allowing the bag contents to be passed via gravity through the tubing set. A conventional spike is hollow throughout and allows a fluid or solution to flow through a tip-end of the sharp hollow spike from the drip bag. The fluid or solution will continue to flow until the meniscus of the fluid/solution in the drip bag falls below the tip-end of the spike, leaving some residual fluid/solution in the bag.
Gravity-fed access to fluids may be used for other containers as well. For example, glass vials with a rubber septum covering may employ gravity-fed access. A spike and tubing set may provide access to a fluid from an inverted septum-covered vial as well. While drip bags typically contain a relatively large volume of fluid (such as 500 mL to 1000 mL), glass vial containers may include significantly less material (such as 10 mL or less). Moreover, fluids or solutions supplied in containers containing such small quantities tend to be expensive. As a result, fluid waste may result in a significant cost.
The invention described in this document is not limited to the particular systems, methodologies or protocols described, as these may vary. The terminology used herein is for the purpose of describing particular embodiments only, and is not intended to limit the scope of the present disclosure.
It must be noted that as used herein and in the appended claims, the singular forms “a,” “an,” and “the” include plural reference unless the context clearly dictates otherwise. Unless defined otherwise, all technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art. As used herein, the term “comprising” means “including, but not limited to.”
In an embodiment, a spike for fluid administration may include a hollow access tube extending from a proximal end of the spike to a distal end of the spike, a platform surrounding the hollow access tube at a location between the distal end and the proximal end, and a sharp tip-end located at the distal end of the spike. The hollow access tube has a central bore and a sidewall. Each of the central bore and the sidewall may extend from the proximal end to the sharp tip-end. The hollow access tube may include at least one opening extending from the central bore to the sidewall and located between the platform and the sharp tip-end.
In an embodiment, a spike and tubing set for fluid administration may include a spike and a flexible tube. The spike may include a hollow access tube extending from a proximal end of the spike to a distal end of the spike, a platform surrounding the hollow access tube at a location between the distal end and the proximal end, and a sharp tip-end located at the distal end of the spike. The hollow access tube has a central bore and a sidewall. Each of the central bore and the sidewall may extend from the proximal end to the sharp tip-end. The hollow access tube may include at least one opening extending from the central bore to the sidewall and located between the platform and the sharp tip-end. The flexible tube may be configured to connect to the hollow access tube and to deliver fluid from the hollow access tube to a fluid administration location.
In an embodiment, a fluid administration system may include a fluid container, a spike, and a flexible tube. The fluid container may include a septum and may contain a fluid. The spike may include a hollow access tube extending from a proximal end of the spike to a distal end of the spike, a sealing surface surrounding the hollow access tube at a location between the distal end and the proximal end, and a sharp tip-end located at the distal end of the spike. The hollow access tube has a central bore and a sidewall. Each of the central bore and the sidewall may extend from the proximal end to the sharp tip-end. The hollow access tube may include at least one opening extending from the central bore to the sidewall and located between the sealing surface and the sharp tip-end. The flexible tube may be configured to connect to the hollow access tube and to deliver fluid from the hollow access tube to a fluid administration location.
The present disclosure discloses hollow spikes for use with a small-volume glass vial or any other fluid container to reduce the amount of waste fluid retained in the container after fluid administration.
The hollow access tube 110 may include a central bore and a sidewall that each extend from the proximal end to the sharp-tip end 160. The central bore may be configured to enable a fluid to pass therethrough when the spike 100 is inserted into a fluid container (as further described herein). In an embodiment, the sharp-tip end 160 may permit a fluid to pass therethrough to the central bore of the hollow access tube 140, 110. The sidewall may be configured to surround the central bore and be substantially solid (except as described herein). The portion (i.e., 140) of the hollow access tube 110 that is distal from the platform 130 may include at least one opening, such as 150a-f. Each opening 150a-f may extend from the central bore to the sidewall. As such, fluid may flow via at least one of the one or more openings 150a-f to the central bore of the hollow access tube 140, 110.
In the embodiment shown in
In an alternate embodiment depicted in
In yet another embodiment depicted in
In an embodiment, the spike may further include a vent tube 120. The vent tube 120 may be configured to equalize a pressure in a container in which the spike, such as 100, is inserted as fluid is withdrawn from the container. In an embodiment, the vent tube 120 may include an air filter 125 to filter and/or sterilize the air that equalizes the pressure within the container. In an embodiment, the air filter 125 may be hydrophobic so that air may pass through, but fluid will not exit the vent tube 120.
In an embodiment, a tube (not shown) may be attached to the proximal end of the spike, such as 100. The tube may be configured to connect to the hollow access tube 110. The tube may be configured to deliver fluid from the hollow access tube 110 to a fluid administration location, such as a needle or other injection device inserted into a patient. In an embodiment, the tube may be flexible.
The spike embodiments 100-300 disclosed above may each enable fluid to flow through not only the sharp tip-end 160 of the spike, but also through the one or more openings, such as 150a-f, 210, or 310a-k. In this manner, fluid may be withdrawn from a container into which a spike designed according to the teachings of the present disclosure is inserted until the meniscus of the fluid is below the most proximal opening, instead of the sharp tip-end. As such, less fluid will remain in a container into which a spike designed according to the teachings of the present disclosure is inserted than if the fluid could only flow through the tip-end.
The hollow access tube 420 may include a central bore and a sidewall that each extend from the proximal end to the sharp-tip end 470. The central bore may be configured to enable a fluid, such as 490, to pass therethrough when the spike 410 is inserted in a fluid container 480. In an embodiment, the sharp-tip end 470 may permit the fluid 490 to pass therethrough to the central bore of the hollow access tube 450, 420. The sidewall may be configured to surround the central bore and be substantially solid (except as described below). The portion (i.e., 450) of the hollow access tube 420 that is distal from the platform 440 may include at least one opening, such as 460a-d. Each opening 460a-d may extend from the central bore to the sidewall. As such, fluid may flow via at least one of the one or more openings 460a-d to the central bore of the hollow access tube 450, 420.
In the embodiment shown in
In an embodiment, the spike may further include a vent tube 430. The vent tube 430 may be configured to equalize a pressure in a container in which the spike 410 is inserted as fluid is withdrawn from the container. In an embodiment, the vent tube 430 may include an air filter 435 to filter and/or sterilize the air that equalizes the pressure within the container. In an embodiment, the air filter 435 may be hydrophobic so that air may pass through, but fluid will not exit the vent tube 430.
The fluid container 480 may be sealed with a septum 485. The sharp end-tip 470 may be inserted through the septum 485 and pushed until the platform 440 contacts the septum. In this configuration, it may be understood that at least a portion of the distal end 450 of the hollow access tube 420 may extend into the container 480 beyond the interior surface of the septum 485. Fluid 490 within the container 480 may be withdrawn through the distal end 450 of the hollow access tube 420 via either the sharp tip-end 470 or the one or more openings 460a-d. At least one of the one or more openings 460a-d may be between the sharp tip-end 470 and the septum 485. As such, the one or more openings 460a-d may permit fluid flow when the meniscus of the fluid 490 falls below the sharp tip-end 470. Indeed, the one or more openings 460a-d may enable fluid 490 to drain from the container 480 until the meniscus is below the most proximal exposed opening. As a result, less fluid 490 may remain in the container 480 than if the fluid only flowed through the sharp tip-end 470.
In an embodiment, the septum 485 may be tapered towards the distal end 450 of the hollow access tube 420 to enable substantially all of the fluid within the container 480 to be withdrawn. For example, the septum 485 may be tapered outward towards the distal end of the septum. In other words, the septum 485 may be tapered inward towards the proximal end of the septum at a location where the septum is configured to be pierced by the distal end 450 of the hollow access tube 420. In this manner, fluid may be funneled by the septum 485 towards the one or more openings 460a-d in the distal end 450 of the hollow access tube 420 when inserted through the septum.
In an embodiment, a tube (not shown) may be attached to the proximal end of the spike 410. The tube may be configured to connect to the hollow access tube 420. The tube may be configured to deliver the fluid 490 from the hollow access tube 420 to a fluid administration location, such as a needle or other injection device inserted into a patient. In an embodiment, the tube may be flexible.
In an embodiment, a spike according to an embodiment may be used in a gravity-fed fluid administration system. In an embodiment, a spike according to an embodiment may be used in a reduced pressure delivery system, such as drawing a fluid from a container in to a syringe.
The spike 505 may be located substantially at a center of the cap assembly 500. In an embodiment, the cap assembly 500 may include a threaded inner surface 515 surrounding the spike 505. The threaded inner surface 515 may be used to affix the cap assembly 500 to a container having a threaded portion surrounding a septum. When attached to a container, the spike 505 may pierce a septum of the container, and the cap assembly 500 may be engaged via the threads with a threaded portion of the container. Indeed, the mechanical advantage of the threading action of the cap assembly 500 may assist in piercing the septum of a container. Moreover, the cap assembly 500 may be prevented from rotating and/or moving axially when the spike 505 is installed. Other methods of affixing a cap assembly 500 to a container are also considered within the scope of this disclosure and will be apparent to those of ordinary skill in the art.
In an embodiment, the cap assembly 500 may be used to removably attach and/or secure the spike 505. The cap assembly 500 may be particularly useful for a high pressure administration process (i.e., where the fluid container has a pressure that is above atmospheric pressure). In addition, the cap assembly 500 may be used for a gravity-fed administration process to ensure that the spike 505 does not separate from the container during administration of the fluid. The cap assembly 500 may be used for alternate or additional administration processes within the scope of this disclosure.
In an embodiment, the sealing surface 530 may be tapered such that the sealing surface at the portion surrounding the spike may be proximal with respect to the edges of the sealing surface. In such an embodiment, pressurized gas (for a high pressure administration system) and/or fluid is directed towards the spike 505 across the septum 525 and against the sealing surface 530 so that the pressurized gas or fluid may not be trapped between the septum 525 and the sealing surface 530.
In an embodiment, the spike 505 may allow fluid to be in fluid communication with the septum 525 and the sealing surface 530. In other words, the spike 505 may be configured to fluidly connect the fluid container 520 to a space between the septum 525 and the sealing surface 530 when the spike is inserted through the septum. In an embodiment, the one or more channels 510 of the spike may be located on both a portion of the spike 505 that is distal of the septum 525 and a portion of the spike that is proximal of the septum, but distal of the sealing surface 530 when the spike is inserted into the fluid container 520. In an alternate embodiment, the one or more channels 510 may extend from a portion of the spike 505 that is distal of the septum 525 to a portion of the spike that is proximal of the septum, but distal of the sealing surface 530 when the spike is inserted into the fluid container 520.
During administration, the fluid may pass through the channel in the spike 505 to a delivery tube 535.
In an embodiment, an O-ring may be used to form a seal in lieu of or in addition to the sealing surface 530 of
It will be appreciated that various of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. It will also be appreciated that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which alternatives, variations and improvements are also intended to be encompassed by the following claims.