US20080255473A1 - Systems, methods, and devices for sampling bodily fluid - Google Patents
Systems, methods, and devices for sampling bodily fluid Download PDFInfo
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- US20080255473A1 US20080255473A1 US12/036,787 US3678708A US2008255473A1 US 20080255473 A1 US20080255473 A1 US 20080255473A1 US 3678708 A US3678708 A US 3678708A US 2008255473 A1 US2008255473 A1 US 2008255473A1
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- Prior art keywords
- fluid
- test strip
- sampling device
- sample
- fluid sampling
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/157—Devices characterised by integrated means for measuring characteristics of blood
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/145—Measuring characteristics of blood in vivo, e.g. gas concentration, pH value; Measuring characteristics of body fluids or tissues, e.g. interstitial fluid, cerebral tissue
- A61B5/1486—Measuring characteristics of blood in vivo, e.g. gas concentration, pH value; Measuring characteristics of body fluids or tissues, e.g. interstitial fluid, cerebral tissue using enzyme electrodes, e.g. with immobilised oxidase
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150007—Details
- A61B5/150015—Source of blood
- A61B5/15003—Source of blood for venous or arterial blood
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150007—Details
- A61B5/150206—Construction or design features not otherwise provided for; manufacturing or production; packages; sterilisation of piercing element, piercing device or sampling device
- A61B5/150213—Venting means
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150007—Details
- A61B5/150206—Construction or design features not otherwise provided for; manufacturing or production; packages; sterilisation of piercing element, piercing device or sampling device
- A61B5/150221—Valves
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150007—Details
- A61B5/150206—Construction or design features not otherwise provided for; manufacturing or production; packages; sterilisation of piercing element, piercing device or sampling device
- A61B5/150259—Improved gripping, e.g. with high friction pattern or projections on the housing surface or an ergonometric shape
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150007—Details
- A61B5/150358—Strips for collecting blood, e.g. absorbent
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150007—Details
- A61B5/150763—Details with identification means
- A61B5/150786—Optical identification systems, e.g. bar codes, colour codes
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/15—Devices for taking samples of blood
- A61B5/150992—Blood sampling from a fluid line external to a patient, such as a catheter line, combined with an infusion line; blood sampling from indwelling needle sets, e.g. sealable ports, luer couplings, valves
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B2562/00—Details of sensors; Constructional details of sensor housings or probes; Accessories for sensors
- A61B2562/02—Details of sensors specially adapted for in-vivo measurements
- A61B2562/0295—Strip shaped analyte sensors for apparatus classified in A61B5/145 or A61B5/157
Definitions
- the invention relates to medical systems, methods, and devices, more specifically, the invention relates to a fluid sampling system.
- the condition of a patient can require that an intravenous/intra-arterial tube or catheter be inserted into a blood vessel.
- the patient's blood vessel can be connected by the tube to a source of fluid which can provide fluid, such as a medicament, and which can also be connected to a pressure transducer that senses the pressure within the patient's blood vessel.
- the likelihood of a health care worker being inadvertently stuck can increase, thereby increasing the risk of infection from a contaminated needle.
- blood can be drawn through the tube already connected to the patient's blood vessel.
- the tube connected to the patient's blood vessel can contain fluid other than blood, such as saline solution and some medication, it is useful to draw the patient's blood up into the tube so that a blood sample can be obtained which is substantially unadulterated by the fluid which is being supplied to the tube by an external source. After the substantially unadulterated blood has been drawn up the tube to a sampling site, the blood sample can be collected into a sample container.
- many of the previously available devices require two-handed operation by a medical practitioner.
- Some of the previous devices utilize a conventional medical syringe to create the suction necessary to draw the blood up the tube.
- Such syringes are often unwieldy to use and their typical long, narrow dimensions makes them cumbersome.
- Many of the previously available devices are complicated and expensive.
- some of the previously available devices include sharp bends in the fluid path and/or relatively long supplementary fluid paths both of which result in residual blood and fluid remaining in the fluid path which can cause problems such as clotting.
- Example embodiments of the medical system described herein can enable the user more freedom to deal with positional lines, obtain glucose readings and can save time by initiating the testing process.
- This system can accomplish various significant improvements over the prior art while still garnering the significant benefits of intensive insulin therapy and being adaptable to nearly all hospitals.
- One benefit of the present invention is that it can reduce pain and discomfort of patients by reducing repeated finger pricking and venous sticks to obtain lab samples. Further, the present invention can decrease the time necessary for practitioners to ascertain patient's glucose levels and obtain blood samples for lab use. Another benefit of the present invention is that it can decrease the risk to practitioners and patients by reducing the need for needles used in the transfer of blood from sample ports to the test strip, and those used with phlebotomy. Additionally, the present invention can decrease cross contamination risk by utilizing a contained blood sample within the sampling device.
- Example embodiments of the medical system of the present invention can include a medical device for drawing a patient's blood into an intravenous tube.
- the medical device can include a housing having a fill chamber into which a patient's blood can be drawn.
- the fill chamber can be in fluid communication with a patient injection site, such as a sample port of an intravenous tube.
- a piston can be positioned within the fill chamber.
- the outer edge of the piston and the interior walls of the fill chamber can be configured to substantially create a seal between the piston and the interior walls of the fill chamber.
- the piston can be moved from a first position to a second position, which can create a negative pressure within the fill chamber that can draw fluid from the patient injection site into the fill chamber.
- the present embodiment can also include biasing means, such as a spring or fluid pressure in the line or tube, for biasing the piston to the second position.
- biasing means such as a spring or fluid pressure in the line or tube
- the medical system can further include securing means, such as clamps, engaging ridges, and the like, for selectively securing the piston in the first and/or second positions.
- the medical system can also include a medical device for sampling bodily fluid, such as blood.
- the fluid sampling device can comprise a base portion and a top portion.
- the base portion can include a blunt canula that can be inserted into a sample port of an intravenous tube or catheter.
- the base portion can also have a handle for a user to hold and which facilitates use of the medical device.
- Extending around at least a portion of the base portion's outer edge can be a ridge that can be configured to engage the top portion.
- the top portion can include a flange adapted to engage the base portion's ridge in order to couple the top portion to the base portion.
- the top portion and the base portion are designed to couple together with a test strip movably disposed therebetween.
- the fluid sampling device can also include a protective housing for preventing undesired damage or contamination of the fluid sampling device.
- a fluid sampling device can comprise a base portion and a test strip mounted thereon.
- the base portion can include a blunt canula that can be inserted into a sample port of an intravenous tube or catheter.
- the base portion can have a handle for a user to hold and which facilitates use of the medical device.
- the top surface of the base portion can define a receiving portion adapted to receive the test strip.
- the test strip can be coupled or fastened to the base portion.
- the medical device can be adapted to direct the bodily fluid sample through the blunt canula and onto the test strip.
- the fluid sampling device can also include a protective housing for preventing undesired damage or contamination of the fluid sampling device.
- a fluid sampling device can comprise a test strip housing and a test strip at least partially disposed within the test strip housing.
- the test strip housing can include a blunt canula that can be inserted into a sample port of an intravenous tube or catheter.
- the test strip housing can also have test strip receptacle with an interior portion adapted to receive the test strip therein.
- the test strip can be coupled or fastened within the test strip receptacle.
- the test strip receptacle and the blunt canula can be coupled together with a connecting portion.
- the medical device can be adapted to direct the bodily fluid sample through the blunt canula and onto the test strip.
- FIG. 1 illustrates the fluid sampling system according to one embodiment of the present invention
- FIG. 2A illustrates a cross-sectional view of a fluid drawing device according to one embodiment of the present invention
- FIG. 2B illustrates a cross-sectional view the fluid drawing device of FIG. 2A after the fluid drawing device has been activated
- FIG. 3 illustrates a cross-sectional view of an alternate example embodiment of a fluid drawing device of the present invention
- FIG. 4A illustrates a top view of a fluid sampling device according to one embodiment of the present invention
- FIG. 4B illustrates a side view of the fluid sampling device of FIG. 4A ;
- FIG. 5A illustrates a top view of an alternative embodiment of the fluid sampling device of the present invention
- FIG. 5B illustrates a bottom view of the alternative embodiment of the fluid sampling device of FIG. 5A ;
- FIG. 5C illustrates a cross-sectional view of the alternative embodiment of the fluid sampling device of FIG. 5A ;
- FIG. 5D illustrates a cross-sectional side view of the alternative embodiment of the fluid sampling device of FIG. 5A ;
- FIG. 6 illustrates a cross-sectional side view of another alternative embodiment of the fluid sampling device of FIG. 5A ;
- FIG. 7 illustrates a modified glucometer according to one embodiment of the present invention
- FIG. 8 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention.
- FIG. 9A illustrates an end view of the top portion of the fluid sampling device of FIG. 8 ;
- FIG. 9B illustrates a side view of the top portion of the fluid sampling device of FIG. 8 ;
- FIG. 9C illustrates a bottom view of the top portion of the fluid sampling device of FIG. 8 ;
- FIG. 10A illustrates an end view of the base portion of the fluid sampling device of FIG. 8 ;
- FIG. 10B illustrates a side view of the base portion of the fluid sampling device of FIG. 8 ;
- FIG. 10C illustrates a top view of the base portion of the fluid sampling device of FIG. 8 ;
- FIG. 11 illustrates a cross-sectional end view of the fluid sampling device of FIG. 8 ;
- FIG. 12 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention.
- FIG. 13A illustrates a side view of the base portion of the fluid sampling device of FIG. 12 ;
- FIG. 13B illustrates a top view of the base portion of the fluid sampling device of FIG. 12 ;
- FIG. 14 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention.
- FIG. 15 illustrates a perspective view of the base portion of the fluid sampling device of FIG. 14 ;
- FIG. 16 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention.
- FIG. 17A illustrates a top perspective view of the base portion of the fluid sampling device of FIG. 16 ;
- FIG. 17B illustrates a bottom perspective view of the base portion of the fluid sampling device of FIG. 16 ;
- FIG. 18A illustrates a top perspective view of the test strip of the fluid sampling device of FIG. 16 ;
- FIG. 18B illustrates a bottom perspective view of the test strip of the fluid sampling device of FIG. 16 ;
- FIG. 19 illustrates a perspective view of a fluid sampling device according to yet another embodiment of the present invention.
- FIG. 20 illustrates an end view of the housing portion of the fluid sampling device of FIG. 19 ;
- FIG. 21 illustrates a exemplary fluid sampling devices according to the present invention associated with a glucometer
- FIG. 22A illustrates a perspective view of a fluid sampling device according to one embodiment of the present invention disposed within a protective packaging
- FIG. 22B illustrates a partial cross-sectional view of the protective packaging of FIG. 22A .
- Embodiments of the present invention described herein relate to a fluid sampling system.
- the fluid sampling system can include a fluid drawing device, a fluid sampling device, and a modified glucometer to accommodate the fluid sampling device.
- Other standard medical equipment used in conjunction with these elements can include a pressure transducer, an IV stand, a pressure bag, saline solution, IV tubing, and a peripheral IV, an Arterial Line or a Central Venous Line, for example.
- the fluid drawing device of the fluid sampling system can be used to draw bodily fluid, such as blood, from a patient injection site into an IV tube or catheter. After the fluid has been drawn into the IV tube, the fluid sampling device can be introduced into a sample port of the IV tube to retrieve a sample of the bodily fluid. After a fluid sample has been retrieved, the fluid sample can be analyzed with a glucometer that can be modified to accommodate the fluid sampling device.
- the fluid sampling system of the present invention can provide a safe method of obtaining a sample of bodily fluid from a patient. For instance, the fluid sampling system can reduce the need to use needles each time a blood sample is needed, which in turn can reduce the pain and discomfort a patient experiences each time he or she is pricked. Further, the possibility that a health care worker will be pricked with a contaminated needle can be reduced with use of the fluid sampling system. Additionally, the fluid sampling system can be simple to use, thus allowing health care workers to focus on other aspect of the patient's treatment.
- a test strip can be any device capable of detecting attributes of a fluid sample.
- a test strip can comprise a substrate with an absorbent material and a reagent disposed thereon.
- a test strip can comprise electrical leads or connections which can communicate various properties of a fluid sample to an analysis device, such as a glucometer. It will be appreciated that a test strip can also comprise a combination of any one or more of a reagent, an absorbent material, and electrical connections.
- test strip having an absorbent material and/or a reagent can be replaced with a test strip having electrical connections.
- an IV tube is connected to a pressure bag (or a pressure transducer) at one end thereof, while the other end of the IV tube is in fluid communication with a patient injection site.
- the present example embodiments also have a fluid drawing device connected to the IV tube between the pressure bag and the patient such that fluid flowing through the IV tube also flows through the fluid drawing device.
- the IV tube also includes a sample port between the fluid drawing device and the patient. The fluid sampling device can be inserted into the sample port in order to take a sample of the fluid in the IV tube.
- a user can take a sample of a patient's bodily fluid, such as blood, by activating the fluid drawing device, which draws the bodily fluid into the IV tube past the sample port, allowing the user to access the bodily fluid at the sample port with the fluid sampling device.
- the fluid drawing device has a fill chamber through which the fluid from the IV tube can flow. Disposed within the fill chamber is a plunger that can be positioned between a first position and a second position. The plunger can be locked in the first and/or the positions. To activate the fluid drawing device, the user releases the locking mechanism on the plunger.
- the plunger can move toward the second position, thus creating a negative pressure in the IV tube, which draws the bodily fluid into the IV tube past the sample port.
- the user can then insert the fluid sampling device into the sample port to retrieve a sample of the bodily fluid.
- the fluid sampling device can be removed from the sample port and the user can depress the plunger of the fluid drawing device to force the extra bodily fluid back into the patient.
- the fluid sampling device can be configured to have a test strip disposed therein. When the bodily fluid enters the fluid sampling device from the sample port, the bodily fluid can be absorbed by the test strip. The sample of bodily fluid absorbed by the test strip can then be analyzed by a glucometer.
- an exemplary embodiment of the fluid sampling system 50 can include an IV tube 102 , a fluid drawing device 100 , a sample port 126 , and a fluid sampling device 200 and/or 400 .
- Fluid drawing device 100 is in fluid communication with IV tube 102 such that fluid drawing device 100 can draw fluid through IV tube 102 past sample port 126 .
- fluid sampling device 200 or 400 can be introduced into sample port 126 to obtain a fluid sample.
- FIGS. 2A-2B illustrate an exemplary embodiment of fluid drawing device 100 .
- fluid drawing device 100 comprises a housing 140 , a piston 142 partially disposed within housing 140 , locking mechanism 150 connected to piston 142 , a cap 144 coupled to the top of housing 140 , and a spring 146 .
- Housing 140 of fluid drawing device 100 is in fluid communication with IV tube 102 such that fluid flowing through IV tube 102 flows from a first portion of IV tube 102 through housing 140 and into a second portion of IV tube 102 .
- first valve 160 is a one-way valve that allows fluid to flow from the first portion of IV tube 102 into housing 140 .
- Second valve 162 is configured to allow fluid to flow both into and out of housing 140 .
- the direction of fluid flow through second valve 162 is determined by the pressure in the system.
- first and second valves 160 and 162 are not incorporated into the system.
- IV tube 102 and valves 162 can be made of a medical grade plastic and/or rubber.
- Cap 144 connects to the top portion of housing 140 . Extending out from cap 144 are cap handles 152 . Cap handles 152 are sized and shaped to assist a user in compressing piston 142 into its first position, as seen in FIG. 2A . Cap 144 has at least one opening therein to allow portions of piston 142 and locking mechanism 150 to extend therethrough. Cap 144 is configured to restrict the movement of piston 142 such that the first end of piston 142 remains within housing 140 . Coupled to a bottom surface of cap 144 is a sterility liner 164 . Sterility liner 164 also couples to piston 142 (described below).
- Sterility liner 164 can be coupled to cap 144 and piston 142 by any suitable means, such as clamps, O-rings, glue, and the like. Sterility liner 164 functions to prevent the interior of housing 140 from becoming contaminated. When piston 142 is in the position illustrated in FIG. 2A , a portion of the interior of housing 140 is exposed. To prevent the interior walls of housing 140 from becoming contaminated, Sterility liner 164 is used to enclose at least a portion of the interior of housing 140 so as to prevent contamination of the interior walls of housing 140 . Without sterility linter 164 , housing 140 could become contaminated, which contamination would enter the fluid sampling system when piston 142 is moved to the position illustrated in FIG. 2B . Such contamination could expose a risk to a patient. Sterility liner 164 can be made of an air-impermeable material, such as a film of plastic.
- a first end of piston 142 is slidably disposed within housing 140 . Extending around the edge of the first end of piston 142 is a seal 148 . Seal 148 abuts the interior wall of housing 140 , creating an airtight seal between piston 142 and housing 140 such that movement of piston 142 within housing 140 causes an increase or decrease in pressure within housing 140 . Seal 148 can be an integral part of piston 142 or it can be a distinct piece adapted to be coupled to the first end of piston 142 . Seal 148 can be made of a medical grade plastic and/or rubber.
- Piston 142 has a rod 154 that extends from the first end of piston 142 and through cap 144 .
- Spring 146 is concentrically placed around rod 154 . The first end of spring 146 rests on the top of cap 144 .
- Rod 154 has a rim 156 that extends over the second end of spring 146 , thus retaining spring 146 between cap 144 and rim 156 .
- locking mechanism 150 In addition to rod 154 , extending from the first end of piston 142 is locking mechanism 150 .
- locking mechanism 150 comprises two levers 150 a , 150 b that extend from opposing sides of the first end of piston 142 through cap 144 .
- Levers 150 a and 150 b are biased toward housing 140 .
- Each of levers 150 a and 150 b has a notch 158 in an outer surface thereof that is sized and shaped to engage cap 144 , thus preventing movement of piston 142 relative to housing 140 .
- Levers 150 a and 150 b can be compressed toward rod 154 to disengage notches 158 from cap 144 , thus allowing piston 142 to move relative to housing 140 .
- piston 142 When cap 144 engages notches 158 , piston 142 is held in the position shown in FIG. 2A . As can be seen, even when spring 146 is compressed and locking mechanism 150 is preventing movement of piston 142 , there is sufficient space between housing 140 and the first end of piston 142 to allow fluid to flow therethrough.
- fluid drawing device 100 is connected to IV tube 102 and piston 142 is locked in the down position illustrated in FIG. 2A .
- a user activates fluid drawing device 100 by compressing levers 150 a and 150 b to disengage piston 142 from housing 140 .
- spring 146 biases piston 142 upward to the position illustrated in FIG. 2B .
- a negative pressure is created in housing 140 causing first valve 160 to close, preventing fluid from flowing from the first portion of IV tube 102 into housing 140 .
- the negative pressure created in housing 140 when piston 142 moves upward draws the fluid in the second portion of IV tube 102 back into housing 140 .
- Spring 146 is designed to have sufficient travel and force to provide the necessary displacement to draw fluid, such as blood, from a patient into the second portion of IV tube 102 .
- fluid such as blood
- Spring 146 is designed to have sufficient travel and force to provide the necessary displacement to draw fluid, such as blood, from a patient into the second portion of IV tube 102 .
- a negative pressure is created in the second portion of IV tube 102 , which in turn draws fluid from the patient's body back into the second portion of IV tube 102 past sample port 126 .
- the user can then insert the fluid sampling device (described in detail below) into sample port 126 to retrieve the desired fluid sample.
- the negative pressure in housing 140 does not exceed that which is produced during regular phlebotomy by commonly used vacuum packed test tubes.
- the user can return the system to it original configuration (as seen in FIG. 2A ) by pressing piston 142 back to its original position which re-infuses the patient's fluid into their body.
- piston 142 is depressed, locking mechanism 150 can be re-engaged and fluid flow through the system can be restored to its original rate.
- the various components of the fluid drawing device can be made from a medical device industry standard, including, but not limited to thermoplastics, such as Polyethylene (PE), High Density Polyethylene (HDPE), Polypropylene (PP), Polystyrene (PF), Polyethylene Terephthalate (PET), and acrylic (for elements that are desired to be transparent, such as chambers 106 , 110 and housing 140 , for example), because of their low cost production, ability to be easily molded, sterility, and strength.
- Spring 146 can be made of steel or any other resilient metal or plastic material. It will be understood by one of ordinary skill in the art in view of the disclosure provided herein that spring 146 can be a flexible member used to store mechanical energy.
- FIG. 3 illustrates an alternative exemplary embodiment of the fluid drawing device 100 .
- the fluid drawing device 100 comprises a driver plunger 104 , the first end of which is disposed within a driver chamber 106 .
- the first end of driver plunger 104 has a driver ridge 118 that sealingly engages the interior wall of driver chamber 106 .
- Driver ridge 118 can be an integral part of driver plunger 104 or it can be a distinct piece adapted to couple to the first end of driver plunger 104 . In either configuration, driver ridge 118 is adapted to create an airtight seal between driver plunger 104 and driver chamber 106 such that movement of driver plunger 104 within driver chamber 106 causes a corresponding change in pressure within driver chamber 106 .
- Driver ridge 118 can be made of a medical grade plastic or rubber.
- the second end of driver plunger 104 comprises a driver handle 122 which extends outside of driver chamber 106 .
- the second end of driver plunger 104 also has a locking mechanism 114 disposed thereon.
- Locking mechanism 114 comprises at least one leaf spring type structure that extends away from a side of driver plunger 104 and that can engage an interior surface of driver chamber 106 to prevent driver plunger 104 from moving relative to driver chamber 106 .
- Locking mechanism 114 can be compressed to disengage driver plunger 104 from driver chamber 106 , thus allowing driver plunger 104 to move relative to driver chamber 106 .
- Fluid drawing device 100 also has a fluid fill plunger 108 , the first end of which is disposed within a fluid fill chamber 110 .
- the first end of fluid fill plunger 108 has a ridge 120 that sealingly engages the interior wall of fluid fill chamber 110 .
- Ridge 120 can be an integral part of fluid fill plunger 108 or it can be a distinct piece adapted to couple to the first end of fluid fill plunger 108 . In either configuration, ridge 120 is adapted to create an airtight seal between fluid fill plunger 108 and fluid fill chamber 110 such that movement of fluid fill plunger 108 within fluid fill chamber 110 causes a corresponding change in pressure within fluid fill chamber 110 .
- Ridge 120 can be made of a medical grade plastic or rubber.
- the second end of fluid fill plunger 108 comprises a fluid fill plunger handle 124 which extends outside of fluid fill chamber 110 .
- Driver plunger handle 122 and fluid fill plunger handle 124 can be connected with connector lock 116 so that the movement of driver plunger 104 and fluid fill plunger 108 is connected.
- connector lock 116 When locking mechanism 114 is engaged with driver chamber 106 , thus restricting movement of fluid fill plunger 108 through connector lock 116 , a space between the bottom of fluid fill chamber 110 and the bottom surface of fluid fill plunger 108 is created that is sufficient to allow fluid to flow therethrough.
- Driver chamber 106 and fluid fill chamber 110 are in fluid communication with each other and with IV tube 102 .
- a fluid in IV tube 102 can flow through driver chamber 106 , into fluid fill chamber 110 , and on into a second portion of IV tube 102 .
- the second portion of IV tube 102 has a sample port 126 into which a user may insert a fluid sampling device 200 or 400 to retrieve a fluid sample, such as a blood sample.
- Flow gauge 112 is a valve that regulates the amount of fluid that can pass from driver chamber 106 to fluid fill chamber 110 , and thus into the patient.
- Flow gauge 112 can be adjusted by a user to allow a desired amount of fluid to pass from driver chamber 106 to fluid fill chamber 110 .
- flow gauge 112 is configured to allow about 3 cc/hr to flow from driver chamber 104 to fluid fill chamber 110 .
- Flow gauge 112 can also acts as a one-way valve to prevent fluid from flowing from fluid fill chamber 110 to driver chamber 106 .
- fluid drawing device 100 can be connected inline with IV tube 102 which can be used for delivering a fluid, such as saline and/or a medicament to a patient. While fluid is being delivered to a patient through IV tube 102 , driver plunger 104 and fluid fill plunger 108 of fluid drawing device 100 are in the positions illustrated in FIG. 3 .
- a user activates fluid drawing device 100 by compresses locking mechanism 114 which disengages driver plunger 104 from driver chamber 106 .
- the fluid pressure in IV tube 102 causes driver plunger 104 to move up in driver chamber 106 .
- driver plunger 104 Upward movement of driver plunger 104 reduces the pressure in driver chamber 106 causing flow gauge 112 to close, preventing fluid from flowing from driver chamber 106 to fluid fill chamber 110 .
- Connector lock 116 causes fluid fill plunger 108 to move up simultaneously with driver plunger 104 .
- a negative pressure is created in fluid fill chamber 110 which draws the fluid in the second portion of IV tube 102 back into fluid fill chamber 110 .
- a negative pressure is created in the second portion of IV tube 102 , which in turn draws a bodily fluid, such as blood, from the patient back into the second portion of IV tube 102 past sample port 126 .
- fluid sampling device 200 or 400 (described in detail below) to retrieve the desired fluid sample.
- the negative pressure in fluid fill chamber 110 does not exceed that which is produced during regular phlebotomy by commonly used vacuum packed test tubes.
- fluid sampling device 200 or 400 can be removed from sample port 126 .
- the user can then return the system to its original configuration by pressing fluid fill plunger 108 back to its original position which re-infuses the patient's bodily fluid into their body.
- the user can then press the driver plunger 104 back to its original position and re-engage locking mechanism 114 . Once both plungers 104 and 108 are depressed, flow gauge 112 opens and allows the system to deliver the desired amount of fluid to the patient.
- FIGS. 4A and 4B illustrate an exemplary embodiment of the fluid sampling device 200 .
- Fluid sampling device 200 comprises a handle 202 , a blunt canula 204 , and a main body 206 having an interior portion and windows 206 a and 206 b .
- Blunt canula 204 is sized and shaped to fit within sample port 126 (see FIG. 1 ).
- Blunt canula 204 has an opening in an end thereof that is in fluid communication with the interior portion of main body 206 .
- the interior portion of main body 206 is adapted to hold a fluid sample, such as a blood sample.
- Windows 206 a and 206 b are disposed on opposing sides of main body 206 and allow a user to view the interior portion of main body 206 .
- Windows 206 a and 206 b also facilitate analysis of the fluid sample when analyzed by a modified glucometer, as discussed below.
- Handle 202 is ergonomically shaped to allow a user to easily and comfortably hold fluid sampling device 200 with a thumb and forefinger.
- blunt canula 204 can be inserted into sample port 126 .
- a small volume of fluid can be drawn through the blunt canula into the interior portion of main body 206 by pressure, such as hydrostatic, hemodynamic, and/or mechanically induced pressure.
- Windows 206 a and 206 b enable a user to view the fluid sample and determine when a sufficient sample has been obtained.
- Fluid sampling device 200 can then be removed from sample port 126 and the fluid sample can be analyzed by a modified glucometer, as discussed below.
- FIGS. 5A-5D illustrate an alternative exemplary embodiment of fluid sampling device 200 .
- fluid sampling device 200 comprises a handle 202 , a main body 206 , and windows 206 a and 206 b .
- fluid sampling device 200 of the present embodiment comprises a diaphragm 208 , a vacuum chamber 210 disposed within main body 206 , a first channel 212 , a second channel 214 , a lure lock tip 216 , and a testing compartment 218 disposed within main body 206 .
- Vacuum chamber 210 is defined by main body 206 and diaphragm 208 .
- Diaphragm 208 is generally arch shaped and is made from a resilient, pliable material, such as rubber or plastic, so that a user can depress diaphragm 208 to decrease the volume of vacuum chamber 210 .
- Vacuum chamber 210 is in fluid communication with first channel 212 such that when diaphragm 208 is depressed, air from vacuum chamber 210 is expelled through first channel 212 .
- First channel 212 extends from vacuum chamber 210 to testing compartment 218 .
- Testing compartment 218 is disposed within main body 206 and is partially defined by windows 206 a and 206 b which are on opposing sides of main body 206 . Windows 206 a and 206 b allow a user to view the interior of testing compartment 218 and determine when a sufficient sample of fluid has been obtained.
- an absorbent material 220 such as foam
- a testing reagent 222 Within testing compartment 218 is an absorbent material 220 , such as foam, and a testing reagent 222 .
- Absorbent material 220 absorbs and retains a fluid sample that is retrieved from sample port 126 as described below.
- Testing reagent 222 is disposed adjacent absorbent material 220 such that absorbed fluid will contact testing reagent 222 . Testing reagent 222 will react to various attributes of the fluid sample, such as glucose levels of a blood sample.
- Testing compartment 218 is in fluid communication with second channel 214 .
- Second channel 214 extends through lure lock tip 216 and opens at the end of lure lock tip 216 .
- Lure lock tip 216 can be retrofitted with a blunt canula in order to access various applicable systems, such as sample port 126 .
- Fluid sampling device 200 of the present embodiment is used in a manner similar to fluid sampling device 200 of the previous embodiment.
- fluid sampling device 200 can be used to retrieve a fluid sample from sample port 126 .
- the present example embodiment of fluid sampling device 200 does not rely on hydrostatic or hemodynamic pressure to draw fluid from sample port 126 into fluid sampling device 200 . Rather, the present embodiment of fluid sampling device 200 utilizes a negative pressure within vacuum chamber 210 to draw fluid from sample port 126 into fluid sampling device 200 .
- lure lock tip 216 prior to inserting lure lock tip 216 into sample port 126 , a user will depress diaphragm 208 to expel air out of vacuum chamber 210 through first channel 212 , testing compartment 218 , and second channel 214 , thus creating a potential vacuum within vacuum chamber 210 .
- lure lock tip 216 is inserted into sample port 126 (see FIG. 1 ).
- the user then releases diaphragm 208 to return to its original shape and position.
- diaphragm 208 returns to its original position, a negative pressure or vacuum is created within vacuum chamber 210 .
- Vacuum chamber 210 and diaphragm 208 are sized adapted to create a negative pressure within fluid sampling device 200 sufficient to draw a desired quantity of fluid from sample port 126 , through second channel 214 , and into testing compartment 218 .
- absorbent material 220 will absorb the fluid and distribute it across testing reagent 222 .
- Absorbent material 220 also functions to retain fluid within fluid sampling device 200 .
- Windows 206 a and 206 b allow a user to view absorbent material 220 in testing compartment 218 to determine when an adequate fluid sample has been achieved. When a sufficient quantity of fluid has been drawn into testing compartment 218 , the user removes fluid sampling device 200 from sample port 126 .
- a typical glucometer 300 comprises a housing 302 , a keypad 304 , internal analysis apparatus 306 (not shown), and a receptacle 308 for receiving a test strip having a fluid sample, such as a blood sample, disposed thereon.
- the modified glucometer shown in FIG. 7 has a reconfigured receptacle 308 that is designed to receive fluid sampling device 200 therein.
- Receptacle 308 is adapted such that when fluid sampling device 200 is inserted therein, windows 206 a and 206 b are in alignment with an analyzer light (not shown) of modified glucometer 300 .
- the analyzer light of modified glucometer 300 is directed through one or both of windows 206 a and 206 b to analyze various attributes of the fluid sample, such as glucose levels of a blood sample.
- FIG. 6 illustrate yet another exemplary embodiment of fluid sampling device 200 .
- Fluid sampling device 200 of the present embodiment comprises handle 202 , vacuum chamber 210 , diaphragm 208 , testing compartment 218 , lure lock tip 216 , channel 224 , test strip 226 , reagent 228 , and valves 230 .
- Vacuum chamber 210 is in fluid communication with channel 224 to allow air to be expelled from vacuum chamber 210 through channel 224 when diaphragm 208 is depressed. Expulsion of air from vacuum chamber 210 creates a potential vacuum therein.
- Fluid sampling device 200 is adapted to receive a standard test strip 226 disposed at least partially therein.
- test strip 226 is received within testing compartment 218 , vacuum chamber 210 and handle 202 .
- Fluid sampling device 200 can be adapted to receive standard supply test strips such as the SureStep Pro test strip made by LifeScan (a J&J subsidiary).
- Fluid sampling device 200 of the present embodiment is used in a manner similar to the previous embodiments of fluid sampling device 200 equipped with diaphragm 208 . Specifically, a user depresses diaphragm 208 to expel air out of vacuum chamber 210 and create a potential vacuum therein. Lure lock tip 216 , either as illustrated or retrofitted with a blunt canula, is inserted into sample port 126 and diaphragm 208 is released to create a negative pressure within vacuum chamber 210 . The negative pressure within vacuum chamber 210 draws fluid from sample port 126 through channel 224 into testing compartment 218 . Fluid entering testing compartment 218 is absorbed by test strip 226 . Having received a sufficient fluid sample, fluid sampling device 200 can be removed from sample port 126 .
- handle 200 of the present embodiment can be removed to expose an end of test strip 226 .
- Handle 200 can be coupled to fluid sampling device 200 with the use of clamps, clips, or the like.
- test strip 226 can be removed from fluid sampling device 200 for analysis of the fluid sample.
- the fluid sample disposed on test strip 226 can be analyzed using conventional means, such as a typical glucometer that is adapted to receive standard test strips.
- fluid sampling device 200 has one-way valve 230 disposed across the opening through which test strip 226 is inserted.
- FIG. 8 illustrates a perspective view of yet another embodiment of fluid sampling device 400 .
- Fluid sampling device 400 of the present embodiment comprises a top portion 402 and a base portion 404 that are adapted to be coupled together. Top portion 402 and base portion 404 can be couple together in a first position and a second position. In the first position, fluid sampling device 400 can have a test strip 226 disposed between base portion 404 and top portion 402 (as seen in FIGS. 8 and 11 ). It is contemplated that standard test strips, such as the SureStep Pro test strip made by LifeScan (a J&J subsidiary) can be used in combination with fluid sampling device 400 .
- Top portion 402 is biased toward base portion 404 such that when test strip 226 is removed top portion 402 moves toward base portion 404 .
- Fluid sampling device 400 can be configured for insertion within sample port 126 to obtain a fluid sample as illustrated in FIG. 1 .
- top portion 402 can comprise test strip 226 .
- base portion 404 and test strip 226 can be coupled together with a flange, and adhesive such as glue, or a mechanical fastener.
- FIGS. 9A-9C illustrate end, side, and bottom views of top portion 402 .
- top portion 402 comprises a top surface 406 , a bottom surface 408 , flanges 410 , and recess 412 .
- Top surface 402 defines an aperture 434 that can allow a user to view the interior of fluid sampling device 400 to determine when a sufficient fluid sample had been obtained.
- Flanges 410 are disposed on opposing sides of top portion 402 and extend from bottom surface 408 . The ends of flanges 410 are rounded in toward the center of top portion 402 .
- Recess 412 is a cavity in bottom surface 408 .
- the various elements of top portion 402 can be integrally formed as a unitary piece, or the elements can be individually formed and then coupled together. As noted above, top portion 402 can comprise test strip 226 .
- FIGS. 10A-10C illustrate end, side, and bottom views of base portion 404 .
- Base portion 404 comprises a platform 414 , walls 422 , and a blunt canula 426 .
- Platform 414 has a bottom surface 420 and a top surface 416 with grooves 418 therein as seen in FIG. 10C .
- the opposing ends 438 of platform 414 can function as handles to facilitate simple and convenient use of fluid sampling device 400 .
- Walls 422 are disposed on opposing sides of platform 414 . The ends of wall 422 are rounded in toward the center of base portion 404 .
- Walls 422 have first ridges 424 and second ridges 428 extending along its outer surface. As seen best in FIG.
- first ridges 424 are vertically above second ridges 428 and extend further out than second ridges 428 .
- Extending from bottom surface 420 is blunt canula 426 .
- Blunt canula 426 has a lumen 430 extending from a distal end of blunt canula 426 through an aperture 436 in platform 414 . The distal end of blunt canula 426 is adapted to be inserted into sample port 126 to obtain a fluid sample, such as a blood sample.
- FIG. 11 is a cross-sectional end view of fluid sampling device 400 illustrating how top portion 402 and base portion 404 couple together.
- the ends of wall 422 and flanges 410 are rounded.
- the rounded ends of walls 422 and flanges 410 facilitate alignment of top portion 402 and base portion 404 and prevent horizontal movement of top portion 402 relative to base portion 404 .
- the interior surfaces of flanges 410 each has an inwardly projecting ridge 432 that is adapted to engage ridges 424 and 428 .
- top portion 402 is aligned with base portion 404 and flanges 410 extend over walls 422 and ridges 432 engage ridges 424 when test strip 226 is disposed between top portion 402 and base portion 404 .
- Top portion 402 is sized such that when test strip 226 is in place and ridges 432 are engaged with ridges 424 , flanges 410 are deflected slightly away from base portion 404 .
- the deflection in flanges 410 causes top portion 402 to be biased toward base portion 404 . Therefore, when test strip 226 is removed, top portion 402 moves toward base portion 404 until bottom surface 408 of top portion 402 comes into contact with top surface 416 of platform 414 .
- test strip 226 can be couple to base portion 404 with a flange similar to flanges 410 , or test strip 226 can be bonded to base portion with a glue or plastic.
- fluid sampling device 400 will have test strip 226 inserted between top portion 402 and base portion 404 .
- fluid drawing device 100 has been activated and a fluid has been drawn into IV tube 102 past sample port 126
- a user can insert the distal end of blunt canula 426 into sample port 126 .
- Pressure such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid from sample port 126 to enter lumen 430 and move up through base portion 404 and onto test strip 226 .
- fluid sampling device 400 can be removed from sample port 126 .
- Test strip 226 can then be withdrawn from between top portion 402 and base portion 404 and analyzed in a glucometer as described above.
- fluid sampling device 400 can be removed from sample port 126 after a fluid sample has been obtained and a glucometer modified to receive fluid sampling device 400 can be used to analyze the fluid sample.
- test strip 226 can be removed from base portion 404 and the fluid sample can be analyzed with a standard glucometer.
- top portion 402 When fluid, such as blood, is drawn from sample port 126 into fluid sampling device 400 , excess fluid may be received within fluid sampling device 400 and on test strip 226 .
- top portion 402 has recess 412 and base portion 404 has grooves 418 in top surface 416 that cooperate to eliminate these problems.
- grooves 418 act like a squeegee to remove excess fluid from test strip 226 as test strip 226 is withdrawn from fluid sampling device 400 .
- top portion 402 and base portion 404 come together as described above, and grooves 418 and recess 412 cooperate to retain the excess fluid within fluid sampling device 400 .
- FIG. 12 illustrates a perspective view of yet another embodiment of a fluid sampling device, generally denoted at 500 .
- Fluid sampling device 500 of the present embodiment comprises a top portion 502 and a base portion 504 that are adapted to be coupled together in the same manner as top portion 402 and base portion 404 , as illustrated in FIG. 11 .
- Top portion 502 is identical to top portion 402 illustrated in FIGS. 9A-9C .
- base portion 504 is similar to base portion 404 illustrated in FIGS. 10A-10C .
- top portion 502 and base portion 504 are adapted to receive test strip 226 therebetween.
- Fluid sampling device 500 can also be configured for insertion within sample port 126 to obtain a fluid sample in the same manner as fluid sampling device 400 as illustrated in FIG. 1 .
- FIGS. 13A and 13B illustrate side and top views of base portion 504 .
- Base portion 504 comprises a platform 514 , walls 522 , and a blunt canula 526 .
- Platform 514 has a bottom surface 520 and a top surface 516 with groove 518 therein as seen in FIG. 13B .
- the opposing ends 538 of platform 514 can function as handles to facilitate simple and convenient use of fluid sampling device 500 .
- Opposing ends 538 of platform 514 also have retention walls 540 and 542 extending upwardly from top surface 516 .
- Retention walls 540 and 542 are adapted to abut edges 232 and 234 of test strip 226 ( FIG. 12 ) to prevent test strip 226 from being removed from between top portion 502 and base portion 504 .
- test strip 226 can be coupled to top portion 502 and/or base portion 504 with an adhesive such as glue, or a mechanical fastener.
- Walls 522 of base portion 504 are disposed on opposing sides of platform 514 . The ends of wall 522 are rounded in toward the center of base portion 504 . Walls 522 have first ridges 524 and second ridges 528 extending along their outer surfaces. First ridges 524 are vertically above second ridges 528 and extend further out than second ridges 528 in the same manner as first ridges 424 and second ridges 428 as illustrated in FIG. 10A . Walls 522 and first and second ridges 524 and 528 facilitate coupling of base portion 504 to top portion 502 in a manner similar to that of top portion 402 and base portion 404 as illustrated in FIG. 11 .
- Blunt canula 526 Extending from bottom surface 520 of base portion 504 is blunt canula 526 .
- Blunt canula 526 has a lumen 530 extending from a distal end of blunt canula 526 through an aperture 536 in platform 514 .
- the distal end of blunt canula 526 is adapted to be inserted into sample port 126 ( FIG. 1 ) to obtain a fluid sample, such as a blood sample.
- Blunt canula 526 can also include a one-way valve 544 (not shown) to prevent or limit the reflux of air into the IV tube 102 .
- valve 544 is coupled to the distal end of lumen 530 .
- Valve 544 can also be disposed in other positions within lumen 530 .
- Valve 544 can be made of a medical grade plastic and/or rubber.
- fluid sampling device 500 will have test strip 226 inserted between top portion 502 and base portion 504 .
- fluid drawing device 100 has been activated and a fluid has been drawn into IV tube 102 past sample port 126
- a user can insert the distal end of blunt canula 526 into sample port 126 .
- Pressure such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid from sample port 126 to enter lumen 530 and move up through base portion 504 and onto test strip 226 .
- Groove 518 is disposed adjacent aperture 536 and test strip 226 to facilitate the escape of air from test strip 226 , thus enabling the fluid sample to readily flow into test strip 226 .
- fluid sampling device 500 can be removed from sample port 126 .
- Electrical connections 236 can then be inserted into a glucometer, such as glucometer 900 illustrated in FIG. 21 , for analysis.
- Glucometers such as glucometer 900 , are adapted to analyze various properties of the fluid sample absorbed by test strip 226 by determining the electrical properties, such as the resistance, of the fluid sample.
- groove 518 of base portion 504 can also be adapted to receive excess fluid received within fluid sampling device 500 .
- groove 518 extends around aperture 536 to receive excess fluid that flows into fluid sampling device 500 through lumen 530 . It will be appreciated that groove 518 can comprise multiple concentric grooves, or any other configuration of one or more grooves that are adapted to receive excess fluid in fluid sampling device 500 .
- FIG. 14 illustrates a perspective view of still yet another embodiment of a fluid sampling device, generally denoted at 600 .
- Fluid sampling device 600 of the present embodiment comprises a test strip 226 and a base portion 604 that are adapted to be coupled together.
- Test strip 226 can be any one of a variety of test strips having electrical connections 236 or other means for analyzing properties of the fluid sample received by fluid sampling device 600 .
- test strip 226 could be a One Touch Ultra test strip made by LifeScan (a J&J subsidiary) or a Comfort Curve test strip made by Accu-Chek (a Roche subsidiary).
- Base portion 604 has a configuration similar to base portions 404 and 504 of the previous embodiments.
- Fluid sampling device 600 can also be configured for insertion within sample port 126 to obtain a fluid sample in the same manner as the previously discussed fluid sampling devices.
- FIG. 15 illustrates a top perspective view of base portion 604 .
- Base portion 604 comprises a platform 614 , mounting portion 646 , and a blunt canula 626 .
- Platform 614 has a bottom surface 620 and a top surface 616 .
- Mounting portion 646 extends from a first end of base portion 604 to about the middle of base portion 604 , and is generally defined by opposing side walls 648 , end wall 650 , and support surface 652 .
- Support surface 652 has grooves 618 therein for receiving excess fluid in that same manner as groove 518 of fluid sampling device 500 .
- Opposing side walls 648 , end wall 650 , and support surface 652 are adapted to abut edges of test strip 226 such that the shape of mounting portion 646 corresponds to the shape of test strip 226 so as to assist in maintaining test strip 226 in a desired position.
- test strip 226 can be coupled to base portion 604 with an adhesive such as glue, or a mechanical fastener.
- the opposing ends 638 of platform 614 can function as handles to facilitate simple and convenient use of fluid sampling device 600 .
- blunt canula 626 Extending from bottom surface 620 of base portion 604 is blunt canula 626 .
- Blunt canula 626 has a lumen 630 extending from a distal end of blunt canula 626 through aperture 636 in support surface 652 .
- blunt canula 626 is offset toward one end of platform 614 , however, it will be appreciated that base portion 604 can be configured with blunt canula 626 extending from platform 614 in other locations to accommodate various test strips 226 .
- the distal end of blunt canula 626 is adapted to be inserted into sample port 126 ( FIG. 1 ) to obtain a fluid sample, such as a blood sample.
- Blunt canula 626 can also include a one-way valve 644 (not shown) to prevent or limit the reflux of air into IV tube 102 .
- valve 644 is coupled to the distal end of lumen 630 .
- Valve 644 can also be disposed in other positions within lumen 630 .
- Valve 644 can be made of a medical grade plastic and/or rubber.
- fluid sampling device 600 will have test strip 226 coupled to base portion 604 within mounting portion 646 .
- fluid drawing device 100 has been activated and a fluid has been drawn into IV tube 102 past sample port 126
- a user can insert the distal end of blunt canula 626 into sample port 126 .
- Pressure such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid from sample port 126 to enter lumen 630 and move up through base portion 604 and onto test strip 226 .
- Grooves 618 are disposed adjacent aperture 636 and test strip 226 to facilitate the escape of air from test strip 226 , thus enabling the fluid sample to readily flow into test strip 226 .
- fluid sampling device 600 can be removed from sample port 126 .
- Electrical connections 236 can then be inserted into a glucometer, such as glucometer 900 illustrated in FIG. 21 , for analysis.
- Glucometers such as glucometer 900 , are adapted to analyze various properties of the fluid sample absorbed by test strip 226 by determining the electrical properties, such as the resistance, of the fluid sample.
- grooves 618 of base portion 604 can also be adapted to receive excess fluid received within fluid sampling device 600 .
- grooves 618 extend parallel to each other on two opposing sides of aperture 636 to receive excess fluid that flows into fluid sampling device 600 through lumen 630 . It will be appreciated that grooves 618 can comprise one or more grooves that extend around at least a part of aperture 636 .
- FIG. 16 illustrates a perspective view of still yet another embodiment of a fluid sampling device, generally denoted at 700 .
- Fluid sampling device 700 of the present embodiment comprises a test strip 226 and a base portion 704 that are adapted to be coupled together.
- Base portion 704 has a configuration similar to base portion 604 .
- Fluid sampling device 700 can also be configured for insertion within sample port 126 to obtain a fluid sample in the same manner as the previously discussed fluid sampling devices.
- FIGS. 17A and 17B illustrate top and bottom perspective views of base portion 704 .
- Base portion 704 comprises a platform 714 , mounting portion 746 , and a blunt canula 726 .
- Platform 714 has a bottom surface 720 and a top surface 716 .
- Mounting portion 746 is generally defined by opposing side walls 748 , end wall 750 , and support surface 752 .
- Support surface 752 has grooves 718 therein for venting air from test strip 226 as described below.
- Opposing side walls 748 , end wall 750 , and support surface 752 are adapted to abut edges of test strip 226 to assist in maintaining test strip 226 in a desired position.
- One or both of side walls 748 can include a projecting portion 754 that extends toward the middle of mounting portion 746 .
- mounting portion 746 can be configured to fit around specific shaped test strips 226 , as illustrated in FIG. 16 .
- test strip 226 can be coupled to base portion 704 with an adhesive such as glue, or a mechanical fastener.
- the opposing ends 738 of platform 714 can function as handles to facilitate simple and convenient use of fluid sampling device 700 .
- blunt canula 726 Extending from bottom surface 720 of base portion 704 is blunt canula 726 .
- Blunt canula 726 has a lumen 730 extending from a distal end of blunt canula 726 through aperture 736 in support surface 752 .
- blunt canula 726 is offset toward one side of platform 714 to accommodate test strip 226 as described below.
- base portion 704 can be configured with blunt canula 726 extending from platform 714 in other locations.
- the distal end of blunt canula 726 is adapted to be inserted into sample port 126 ( FIG. 1 ) to obtain a fluid sample, such as a blood sample.
- Blunt canula 726 can also include a one-way valve 744 to prevent or limit the reflux of air into IV tube 102 .
- valve 744 is coupled to the distal end of lumen 730 . It will be appreciated that valve 744 can also be disposed in other positions within lumen 730 .
- Valve 744 can be made of a medical grade plastic and/or rubber.
- alignment members 756 which extend from blunt canula 726 toward opposing ends of platform 714 . Alignment members 756 provide a reference point to enable a user to center the blunt canula 726 in their fingers and to determine the center position of the offset blunt canula 726 . Alignment members 756 also add additional mass, and thus strength, to fluid sampling device 700 .
- FIGS. 18A and 18B illustrate one example embodiment of test strip 226 that can be used with fluid sampling device 700 .
- the illustrated embodiment of test strip 226 is a Comfort Curve test strip made by Accu-Chek (a Roche subsidiary).
- test strip 226 can be any one of a variety of test strips having electrical connections 236 or other means for analyzing properties of the fluid sample received by fluid sampling device 700 , such as the One Touch Ultra test strip made by LifeScan (a J&J subsidiary).
- Test strip 226 includes electrical connections 236 , fluid intake 238 , and vent 240 .
- electrical connections 236 can be used in conjunction with a glucometer to analyze the fluid sample retrieved with fluid sampling device 700 .
- Fluid intake 238 can be an opening in the side, or other surface, of test strip 226 .
- Fluid intake 238 is adapted to receive a fluid sample, such as blood, therein. To enable a fluid to readily flow into fluid intake 238 , the air disposed within fluid intake 238 must be removed.
- Vent 240 is in fluid communication with fluid intake 238 and allows the air in fluid intake 238 to escape therefrom as a fluid sample enters fluid into 238 .
- fluid sampling device 700 will have test strip 226 coupled to base portion 704 within mounting portion 746 .
- fluid drawing device 100 has been activated and a fluid has been drawn into IV tube 102 past sample port 126
- a user can insert the distal end of blunt canula 726 into sample port 126 .
- Pressure such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid from sample port 126 to enter lumen 730 and move up through aperture 736 of base portion 704 .
- the fluid sample then enters fluid intake 238 of test strip 226 . Air within fluid intake 238 can escape test strip 226 through vent 240 .
- Grooves 718 are disposed adjacent vent 240 to facilitate the escape of air from test strip 226 through vent 240 , thus enabling the fluid sample to readily flow into test strip 226 .
- fluid sampling device 700 can be removed from sample port 126 .
- Electrical connections 236 can then be inserted into a glucometer, such as glucometer 900 illustrated in FIG. 21 , for analysis.
- Glucometers, such as glucometer 900 are adapted to analyze various properties of the fluid sample absorbed by test strip 226 by determining the electrical properties, such as the resistance, of the fluid sample.
- grooves 618 can also be adapted to receive excess fluid received within fluid sampling device 700 .
- grooves 618 extend parallel to each other on two opposing sides of aperture 636 to receive excess fluid that flows into fluid sampling device 600 through lumen 630 . It will be appreciated that grooves 618 can comprise one or more grooves that extend around at least a part of aperture 636 .
- fluid sampling devices 200 , 400 , 500 , 600 , and 700 can be made from medical device industry standard plastics including, but not limited to thermoplastics, such as Polyethylene (PE), High Density Polyethylene (HDPE), Polypropylene (PP), Polystyrene (PF), Polyethylene Terephthalate (PET), and acrylic (for transparent properties), because of their low cost production, ability to be easily molded, sterility, and strength.
- thermoplastics such as Polyethylene (PE), High Density Polyethylene (HDPE), Polypropylene (PP), Polystyrene (PF), Polyethylene Terephthalate (PET), and acrylic (for transparent properties), because of their low cost production, ability to be easily molded, sterility, and strength.
- FIG. 19 illustrates a perspective view of still yet another embodiment of a fluid sampling device, generally denoted at 800 .
- Fluid sampling device 800 of the present embodiment comprises a test strip 226 and a test strip housing 802 .
- Test strip housing 802 includes a blunt canula 826 and a test strip receptacle 804 for receiving at least a portion of test strip 226 therein.
- Test strip 226 can be any one of a variety of test strips having electrical connections 236 or other means for analyzing properties of a fluid sample received by fluid sampling device 800 .
- test strip 226 could be a One Touch Ultra test strip made by LifeScan (a J&J subsidiary) or a Comfort Curve test strip made by Accu-Chek (a Roche subsidiary).
- Fluid sampling device 800 can also be configured for insertion within sample port 126 to obtain a fluid sample in a manner similar to that of the previously discussed fluid sampling devices.
- test strip receptacle 804 has a generally flat, rectangular shape with an interior portion 806 .
- Interior portion 806 is adapted to receive at least a portion of test strip 226 therein.
- interior portion 806 is sized and configured to generally correspond to the size and shape of test strip 226 such that an end of test strip 226 can be inserted and maintained within test strip receptacle 804 .
- Test strip 226 can be held within interior portion 806 of test strip receptacle 804 by a variety of means, including frictional coupling, mechanical fasteners such as clamps or pins, and adhesives such as glue.
- test strip receptacle 804 can function as a handle to facilitate simple and convenient use of fluid sampling device 800 .
- the walls of interior portion 806 include grooves 818 which provide similar functionality as the grooves described elsewhere herein.
- grooves 818 are adapted to assist in venting air from test strip 226 to enable test strip 226 to readily absorb a fluid sample.
- grooves 818 extend from the opening of interior portion 806 to about the opposing end of test strip receptacle 804 .
- grooves 818 can be otherwise configured.
- grooves 818 can comprise a single groove or grooves 818 can be completely disposed within test strip housing 802 .
- Connecting portion 808 is generally funnel shaped and connects test strip receptacle 804 to blunt canula 826 .
- Blunt canula 826 has a lumen 830 extending from a distal end of blunt canula 826 through aperture 836 in connecting portion 808 .
- Test strip receptacle 804 , connecting portion 808 , and blunt canula 826 can be made from discrete parts and coupled together, such as with an adhesive, or they can be formed as a single integral piece. The distal end of blunt canula 826 is adapted to be inserted into sample port 126 ( FIG.
- Blunt canula 826 can also include a one-way valve 844 (not shown) to prevent or limit the reflux of air into IV tube 102 .
- valve 844 is coupled to the distal end of lumen 830 .
- Valve 844 can also be disposed in other positions within lumen 830 .
- Valve 844 can be made of a medical grade plastic and/or rubber.
- fluid sampling device 800 will have test strip 226 coupled within interior portion 806 of test strip receptacle 804 .
- fluid drawing device 100 has been activated and a fluid has been drawn into IV tube 102 past sample port 126
- a user can insert the distal end of blunt canula 826 into sample port 126 .
- Pressure such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid from sample port 126 to enter lumen 830 and move up through blunt canula 826 and connecting portion 808 and onto test strip 226 .
- Grooves 818 are disposed adjacent test strip 226 to facilitate the escape of air from test strip 226 , thus enabling the fluid sample to readily flow into test strip 226 .
- fluid sampling device 800 can be removed from sample port 126 .
- Electrical connections 236 of test strip 226 can then be inserted into a glucometer, such as glucometer 900 illustrated in FIG. 21 , for analysis.
- Glucometers such as glucometer 900 , are adapted to analyze various properties of the fluid sample absorbed by test strip 226 by determining the electrical properties, such as the resistance, of the fluid sample.
- each of the various fluid sampling devices described herein can also be formed as a single integral piece.
- base portions 504 , 604 , and 704 and test strip housing 802 can each be formed with an integrated test strip or other fluid monitoring technology.
- the fluid sampling devices disclosed herein can be formed with an interior cavity or chamber which is in fluid communication with a blunt canula.
- a fluid monitoring device, such as absorbent material 220 or electrical connections 236 can be at least partially disposed within or in fluid communication with the cavity such that various attributes of the fluid sample can be detected without the use of a conventional test strip.
- a typical glucometer 900 comprises a housing 902 , keys 904 , internal analysis apparatus 906 (not shown), and a receptacle 908 for receiving a test strip having a fluid sample, such as a blood sample, disposed thereon.
- the glucometer shown in FIG. 21 has a receptacle 908 that is designed to receive an end of test strip 226 therein.
- glucometer 900 Disposed within receptacle 908 are electrical connections (not shown) which are adapted for electrical communication with electrical connections 236 of test strip 226 when the end of test strip 226 is inserted within receptacle 908 .
- the internal analysis apparatus 906 of glucometer 900 is adapted to analyze various electrical properties of the fluid sample received on test strip 226 . Such electrical properties can include the resistance, impedance, capacitance and the like of the fluid sample.
- Glucometer 900 is adapted to determine various attributes of the fluid sample, such as the glucose level of a blood sample, based on the electrical properties of the fluid sample.
- FIGS. 22A-22B illustrate an example embodiment of a protective housing 1000 that is adapted to receive one of fluid sampling devices 400 , 500 , 600 , 700 , and 800 therein.
- the example embodiment of protective housing 1000 is shown and described with specific reference to fluid sampling device 400 .
- protective housing 1000 can be employed with any one of fluid sampling devices 400 , 500 , 600 , 700 , and 800 , either as described herein or with minor modifications that will be readily apparent to one of ordinary skill in the art.
- protective housing 1000 comprises substrate 1002 , a railing 1008 , and a cover portion 1010 .
- Substrate 1002 has a top surface 1004 and a bottom surface 1006 that lays adjacent top surface 406 of top portion 402 . Extending from bottom surface 1006 is railing 1008 .
- Railing 1008 extends around fluid sampling device 400 and down to about top surface 416 of platform 414 .
- Substrate 1002 and railing 1008 can be formed as a unitary piece, or can be individually formed and coupled together.
- Cover portion 1010 Attached to the lower edge of railing 1008 is cover portion 1010 .
- Cover portion 1010 extends over blunt canula 426 .
- Cover portion 1010 can comprise two layers of plastic 1010 a and 1010 b with air disposed therebetween. Layers of plastic 1010 a and 1010 b can be bonded together at various points to create pockets of air therein. As shown in FIG. 22B , layers of plastic 1010 a and 1010 b are bonded together near railing 1008 and the distal end of blunt canula 426 , thus creating air pockets 1012 and 1014 .
- cover portion 1010 comprises a single layer of plastic 1010 a that extends from railing 1008 around base portion 404 .
- Protective housing 1000 is adapted to protect fluid sampling device 400 from physical damages prior to use, such as during shipment. Protective housing 1000 also maintains the sterility of fluid sampling device 400 by preventing undesirable contamination through exposure to a non-sterile surface, such as a user's hands.
- Fluid sampling device 400 packaged in protective housing 1000 is used in a manner similar to that described above with respect to fluid sampling device 400 .
- cover portion 1010 must be ruptured prior to inserting blunt canula 426 into sample port 126 .
- a user will hold fluid sampling device 400 , disposed within protective packaging 1000 , with their thumb or palm on top surface 1004 of substrate 1002 , and their index and middle fingers extending around opposing sides of cover portion 1010 . Holding fluid sampling device 400 and protective housing 1000 in this manner, a user can squeeze protective housing 1000 with enough force to rupture air pockets 1012 and 1014 .
- blunt canula 426 can be forced through layers of plastic 1010 a and 1010 b to expose blunt canula 426 . With blunt canula 426 exposed, a user can then insert blunt canula into sample port 126 to obtain a fluid sample in the same manner as previously described.
- one or both of layers of plastic 1010 a and 1010 b of cover portion 1010 can be formed of a resilient material, such as a semi-rigid plastic, a shape memory material, a foam, or a rubber material.
- a resilient cover portion 1010 When employing a resilient cover portion 1010 , a user can obtain a fluid sample in a manner similar to that described above (i.e., compress cover portion 1010 until blunt canula 426 extends through cover portion 1010 and insert blunt canula 426 into sample port 126 ). However, unlike the previously described embodiments, a resilient cover portion 1010 can regain its shape after the user removes pressure from cover portion 1010 .
- protective housing 1000 can be configured so as to expose blunt canula 426 when being inserted into sample port 126 . Reducing the time that blunt canula 426 is exposed, both before and after use, provides numerous benefits. As discussed above, protective housing 1000 can prevent contamination of blunt canula 426 prior to use. Additionally, use of a resilient cover portion 1010 can also reduce the risk of exposure to a user, such as a nurse, by enclosing blunt canula 426 , and any excess fluid thereon, within protective housing 1000 .
- each of fluid sampling devices 400 , 500 , 600 , 700 , and 800 can be disposed within protective housing 1000 .
- protective housing 1000 can accommodate various embodiments of fluid sampling devices.
- bottom surface 1006 of substrate 1002 lays adjacent test strip 226 and top surface 616 or 716 rather than top portion 402 or 502 .
- substrate 1002 can also function to enclose the opening between aperture 736 and fluid intake 238 to assist in directing fluid received through blunt canula 726 into fluid intake 238 of test strip 226 .
- Substrate 1002 can also assist in preventing fluid received within fluid sampling device 700 from leaking out of fluid sampling device 1000 .
- the fluid drawing device can comprise a housing having a fill chamber in fluid communication with a patient injection site.
- a piston can be positionable within the fill chamber to sealingly engage the fill chamber, wherein the piston has a first position and a second position, wherein movement of the piston from the first position to the second position generates a negative pressure in the fill chamber effective to draw fluid from the patient injection site into the fill chamber.
- the fluid drawing device can also include biasing means for biasing the piston to the second position relative to the first position.
- the biasing means can comprise a spring linked to the piston, such that the spring is more compressed when the piston is in the first position than when the piston is in the second position.
- the biasing means is generated by fluid pressure from the patient injection site.
- the biasing means is generated by hydraulic actuation.
- the fluid drawing device can also include securing means for selectively securing the piston in the second position.
- the securing means can comprise a locking system at least partially coupled to the piston.
- the fluid drawing device can comprise a housing having a fill chamber in fluid communication with a patient injection site, a piston disposed and positionable within the fill chamber, the piston being sealingly engaged with the fill chamber to generate a negative pressure in the fill chamber effective to draw fluid from the patient injection site into the fill chamber when the piston is moved from a first position to a second position.
- the fluid drawing device can also include biasing means for biasing the piston to the second position relative to the first position, and securing means for selectively securing the piston in the first position.
- the biasing means of the fluid drawing device can comprise a spring linked to the piston, such that the spring is more compressed when the piston is in the first position than when the piston is in the second position.
- the biasing means can also be generated by fluid pressure from the patient injection site.
- the biasing means can also be generated by hydraulic actuation.
- the securing means can comprise a locking system at least partially coupled to the piston.
- the fluid drawing device can comprise a housing having a fill chamber in fluid communication with a patient injection site, a piston positionable within the fill chamber to sealingly engage the fill chamber, wherein the piston has a first position and a second position, wherein movement of the piston from the first position to the second position generates a negative pressure in the fill chamber effective to draw fluid from the patient injection site into the fill chamber, a spring linked to the piston, wherein the spring is more compressed when the piston is in the first position than when the spring is in the second position, such that the spring tends to bias the piston to the second position relative to the first position; and a locking member coupled to the piston to selectively secure the piston in the first position.
- the locking member can be positionable to engage the housing to secure the piston in the first position.
- the locking member can be configured for selective disengagement from the housing so as to enable the piston to move between the first and the second positions.
- a method of sampling bodily fluid comprises: providing a fluid sampling system, wherein said fluid sampling system comprises an IV tube in fluid communication with a patient injection site, said IV tube having a sample port; a fluid drawing device in fluid communication with said IV tube, said fluid drawing device having a fill chamber and a piston sealingly engaged therein; and a fluid sampling device that is configured to be inserted within said sample port, said fluid sampling device having a blunt canula; drawing a fluid through said IV tube to sample port by activating fluid drawing device, wherein activation of said fluid drawing device comprises moving said piston relative to said fill chamber such that a negative pressure is generated in fluid drawing device sufficient to draw a fluid through IV tube to said sample port; and obtaining a fluid sample from said sample port by inserting said blunt canula into said sample port and drawing fluid into said fluid sampling device by hydrostatic or hemodynamic pressure, or negative pressure.
- the fluid drawing device comprises two fill chambers and two pistons.
- the fluid drawing device further comprises a handle, a main body having an interior portion, and a window in the main body.
- the fluid drawing device is adapted to receive a test strip therein.
- the handle of the fluid drawing device is removable to facilitate removal of the test strip from the fluid drawing device.
- the fluid sampling device has an absorbent material disposed in the interior portion in some embodiments.
- the fluid sampling device further comprises a base portion having a platform and a ridge extending around at least a portion of an outer surface of the base portion; and a top portion having a flange adapted to engage the ridge to couple the top portion to the base portion.
- the fluid sampling device is adapted to receive a test strip between the base portion and the top portion. The fluid sampling device can be configured to allow the test strip to be removed from the fluid sampling device to facilitate analysis of the fluid sample.
Abstract
A fluid sampling system is disclosed comprising a fluid drawing device and a fluid sampling device. In one embodiment, the fluid sampling device comprises a base portion having a canula, a handle, and a ridge extending around at least a portion of an outer surface; and a top portion having a flange adapted to engage said ridge to couple the top portion to the base portion. In another embodiment, the fluid sampling device comprises a base portion having a canula, a handle, a mounting portion, and a test strip coupled to the base portion at least partially within the mounting portion. In yet another embodiment, the fluid sampling device comprises a test strip housing for receiving an end of a test strip therein. Extending from an end of the test strip housing is a blunt canula.
Description
- This application is a continuation-in-part of U.S. patent application Ser. No. 11/765,888, filed Jun. 20, 2007, entitled SYSTEMS, METHODS, AND DEVICES FOR SAMPLING BODILY FLUID, which claims the benefit of U.S. Provisional Application No. 60/805,426, filed Jun. 21, 2006, entitled BLOOD SAMPLING SYSTEM, all of which are hereby incorporated by reference in their entireties.
- 1. The Field of the Invention
- The invention relates to medical systems, methods, and devices, more specifically, the invention relates to a fluid sampling system.
- 2. Relevant Technology
- In some medical procedures, the condition of a patient can require that an intravenous/intra-arterial tube or catheter be inserted into a blood vessel. The patient's blood vessel can be connected by the tube to a source of fluid which can provide fluid, such as a medicament, and which can also be connected to a pressure transducer that senses the pressure within the patient's blood vessel.
- In critical care situations, it can be necessary to periodically obtain samples of the patient's bodily fluids, such as blood. For procedures carried out using a needle stick, the likelihood of a health care worker being inadvertently stuck can increase, thereby increasing the risk of infection from a contaminated needle. Rather than stick a patient with a needle each time blood must be drawn, blood can be drawn through the tube already connected to the patient's blood vessel. Since the tube connected to the patient's blood vessel can contain fluid other than blood, such as saline solution and some medication, it is useful to draw the patient's blood up into the tube so that a blood sample can be obtained which is substantially unadulterated by the fluid which is being supplied to the tube by an external source. After the substantially unadulterated blood has been drawn up the tube to a sampling site, the blood sample can be collected into a sample container.
- Disadvantageously, many of the previously available devices require two-handed operation by a medical practitioner. Some of the previous devices utilize a conventional medical syringe to create the suction necessary to draw the blood up the tube. Such syringes are often unwieldy to use and their typical long, narrow dimensions makes them cumbersome. Many of the previously available devices are complicated and expensive. Moreover, some of the previously available devices include sharp bends in the fluid path and/or relatively long supplementary fluid paths both of which result in residual blood and fluid remaining in the fluid path which can cause problems such as clotting.
- In 2001, a study of 1548 patients was performed to demonstrate the effects of “intensive insulin therapy” on mortality and morbidity. See Greet Van den Bergh, et. al., Intensive Insulin Therapy in Critically Ill Patients, The New England Journal of Medicine, Vol. 345:1359-1367, No. 19, Nov. 8, 2001. The study showed that patients with tightly controlled blood glucose levels (between 80-110 mg/dl) had remarkably improved outcomes. Overall mortality was decreased by 34%, blood stream infections by 46%, acute renal failure requiring dialysis or hemofiltration decreased by 41%, the median number of red cell transfusions by 50% as well as requiring less time on the ventilator and less days in the ICU. Beyond the increased health benefits to patients, this reduces hospital costs by $3000 to $4000 per ICU patient. See http://www.santacruzsentinel.com/archive/2005/February/13/biz/stories/02biz.htm.
- The medical community has been striving for successful implementation of intensive insulin therapy because of the documented benefits of intensive insulin therapy. In order to implement this therapy, patients can have their fingers stuck for glucose readings every hour for days, weeks and even months. This has caused a significant amount of pain and torment to be inflicted to the patients. Additionally, repeated glucose level monitoring can take up valuable time of registered nurses (RNs) and practitioners.
- Example embodiments of the medical system described herein can enable the user more freedom to deal with positional lines, obtain glucose readings and can save time by initiating the testing process. This system can accomplish various significant improvements over the prior art while still garnering the significant benefits of intensive insulin therapy and being adaptable to nearly all hospitals. One benefit of the present invention is that it can reduce pain and discomfort of patients by reducing repeated finger pricking and venous sticks to obtain lab samples. Further, the present invention can decrease the time necessary for practitioners to ascertain patient's glucose levels and obtain blood samples for lab use. Another benefit of the present invention is that it can decrease the risk to practitioners and patients by reducing the need for needles used in the transfer of blood from sample ports to the test strip, and those used with phlebotomy. Additionally, the present invention can decrease cross contamination risk by utilizing a contained blood sample within the sampling device.
- Example embodiments of the medical system of the present invention can include a medical device for drawing a patient's blood into an intravenous tube. The medical device can include a housing having a fill chamber into which a patient's blood can be drawn. The fill chamber can be in fluid communication with a patient injection site, such as a sample port of an intravenous tube. A piston can be positioned within the fill chamber. The outer edge of the piston and the interior walls of the fill chamber can be configured to substantially create a seal between the piston and the interior walls of the fill chamber. The piston can be moved from a first position to a second position, which can create a negative pressure within the fill chamber that can draw fluid from the patient injection site into the fill chamber. The present embodiment can also include biasing means, such as a spring or fluid pressure in the line or tube, for biasing the piston to the second position. The medical system can further include securing means, such as clamps, engaging ridges, and the like, for selectively securing the piston in the first and/or second positions.
- The medical system can also include a medical device for sampling bodily fluid, such as blood. The fluid sampling device can comprise a base portion and a top portion. The base portion can include a blunt canula that can be inserted into a sample port of an intravenous tube or catheter. The base portion can also have a handle for a user to hold and which facilitates use of the medical device. Extending around at least a portion of the base portion's outer edge can be a ridge that can be configured to engage the top portion. The top portion can include a flange adapted to engage the base portion's ridge in order to couple the top portion to the base portion. In some embodiments, the top portion and the base portion are designed to couple together with a test strip movably disposed therebetween. The fluid sampling device can also include a protective housing for preventing undesired damage or contamination of the fluid sampling device.
- Alternative embodiments of a fluid sampling device can comprise a base portion and a test strip mounted thereon. The base portion can include a blunt canula that can be inserted into a sample port of an intravenous tube or catheter. The base portion can have a handle for a user to hold and which facilitates use of the medical device. The top surface of the base portion can define a receiving portion adapted to receive the test strip. The test strip can be coupled or fastened to the base portion. The medical device can be adapted to direct the bodily fluid sample through the blunt canula and onto the test strip. As noted, the fluid sampling device can also include a protective housing for preventing undesired damage or contamination of the fluid sampling device.
- Another alternative embodiment of a fluid sampling device can comprise a test strip housing and a test strip at least partially disposed within the test strip housing. The test strip housing can include a blunt canula that can be inserted into a sample port of an intravenous tube or catheter. The test strip housing can also have test strip receptacle with an interior portion adapted to receive the test strip therein. The test strip can be coupled or fastened within the test strip receptacle. The test strip receptacle and the blunt canula can be coupled together with a connecting portion. The medical device can be adapted to direct the bodily fluid sample through the blunt canula and onto the test strip.
- These and other objects and features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.
- To further clarify the above and other advantages and features of the present invention, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
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FIG. 1 illustrates the fluid sampling system according to one embodiment of the present invention; -
FIG. 2A illustrates a cross-sectional view of a fluid drawing device according to one embodiment of the present invention; -
FIG. 2B illustrates a cross-sectional view the fluid drawing device ofFIG. 2A after the fluid drawing device has been activated; -
FIG. 3 illustrates a cross-sectional view of an alternate example embodiment of a fluid drawing device of the present invention; -
FIG. 4A illustrates a top view of a fluid sampling device according to one embodiment of the present invention; -
FIG. 4B illustrates a side view of the fluid sampling device ofFIG. 4A ; -
FIG. 5A illustrates a top view of an alternative embodiment of the fluid sampling device of the present invention; -
FIG. 5B illustrates a bottom view of the alternative embodiment of the fluid sampling device ofFIG. 5A ; -
FIG. 5C illustrates a cross-sectional view of the alternative embodiment of the fluid sampling device ofFIG. 5A ; -
FIG. 5D illustrates a cross-sectional side view of the alternative embodiment of the fluid sampling device ofFIG. 5A ; -
FIG. 6 illustrates a cross-sectional side view of another alternative embodiment of the fluid sampling device ofFIG. 5A ; -
FIG. 7 illustrates a modified glucometer according to one embodiment of the present invention; -
FIG. 8 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention; -
FIG. 9A illustrates an end view of the top portion of the fluid sampling device ofFIG. 8 ; -
FIG. 9B illustrates a side view of the top portion of the fluid sampling device ofFIG. 8 ; -
FIG. 9C illustrates a bottom view of the top portion of the fluid sampling device ofFIG. 8 ; -
FIG. 10A illustrates an end view of the base portion of the fluid sampling device ofFIG. 8 ; -
FIG. 10B illustrates a side view of the base portion of the fluid sampling device ofFIG. 8 ; -
FIG. 10C illustrates a top view of the base portion of the fluid sampling device ofFIG. 8 ; -
FIG. 11 illustrates a cross-sectional end view of the fluid sampling device ofFIG. 8 ; -
FIG. 12 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention; -
FIG. 13A illustrates a side view of the base portion of the fluid sampling device ofFIG. 12 ; -
FIG. 13B illustrates a top view of the base portion of the fluid sampling device ofFIG. 12 ; -
FIG. 14 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention; -
FIG. 15 illustrates a perspective view of the base portion of the fluid sampling device ofFIG. 14 ; -
FIG. 16 illustrates a perspective view of a fluid sampling device according to another embodiment of the present invention; -
FIG. 17A illustrates a top perspective view of the base portion of the fluid sampling device ofFIG. 16 ; -
FIG. 17B illustrates a bottom perspective view of the base portion of the fluid sampling device ofFIG. 16 ; -
FIG. 18A illustrates a top perspective view of the test strip of the fluid sampling device ofFIG. 16 ; -
FIG. 18B illustrates a bottom perspective view of the test strip of the fluid sampling device ofFIG. 16 ; -
FIG. 19 illustrates a perspective view of a fluid sampling device according to yet another embodiment of the present invention; -
FIG. 20 illustrates an end view of the housing portion of the fluid sampling device ofFIG. 19 ; -
FIG. 21 illustrates a exemplary fluid sampling devices according to the present invention associated with a glucometer; -
FIG. 22A illustrates a perspective view of a fluid sampling device according to one embodiment of the present invention disposed within a protective packaging; -
FIG. 22B illustrates a partial cross-sectional view of the protective packaging ofFIG. 22A . - Embodiments of the present invention described herein relate to a fluid sampling system. The fluid sampling system can include a fluid drawing device, a fluid sampling device, and a modified glucometer to accommodate the fluid sampling device. Other standard medical equipment used in conjunction with these elements can include a pressure transducer, an IV stand, a pressure bag, saline solution, IV tubing, and a peripheral IV, an Arterial Line or a Central Venous Line, for example.
- The fluid drawing device of the fluid sampling system can be used to draw bodily fluid, such as blood, from a patient injection site into an IV tube or catheter. After the fluid has been drawn into the IV tube, the fluid sampling device can be introduced into a sample port of the IV tube to retrieve a sample of the bodily fluid. After a fluid sample has been retrieved, the fluid sample can be analyzed with a glucometer that can be modified to accommodate the fluid sampling device. The fluid sampling system of the present invention can provide a safe method of obtaining a sample of bodily fluid from a patient. For instance, the fluid sampling system can reduce the need to use needles each time a blood sample is needed, which in turn can reduce the pain and discomfort a patient experiences each time he or she is pricked. Further, the possibility that a health care worker will be pricked with a contaminated needle can be reduced with use of the fluid sampling system. Additionally, the fluid sampling system can be simple to use, thus allowing health care workers to focus on other aspect of the patient's treatment.
- In the disclosure, reference is made to the use of a test strip with a fluid sampling device. As used in the disclosure and the claims, a test strip can be any device capable of detecting attributes of a fluid sample. For example, a test strip can comprise a substrate with an absorbent material and a reagent disposed thereon. Alternatively, a test strip can comprise electrical leads or connections which can communicate various properties of a fluid sample to an analysis device, such as a glucometer. It will be appreciated that a test strip can also comprise a combination of any one or more of a reagent, an absorbent material, and electrical connections. While some embodiments herein are described with reference to a specific type of test strip, it will be appreciated that the specific test strip described in each embodiment can be interchanged or replaced with another type of test strip. For example, a test strip having an absorbent material and/or a reagent can be replaced with a test strip having electrical connections.
- In one example embodiment, an IV tube is connected to a pressure bag (or a pressure transducer) at one end thereof, while the other end of the IV tube is in fluid communication with a patient injection site. Unlike typical IV systems, the present example embodiments also have a fluid drawing device connected to the IV tube between the pressure bag and the patient such that fluid flowing through the IV tube also flows through the fluid drawing device. In addition, the IV tube also includes a sample port between the fluid drawing device and the patient. The fluid sampling device can be inserted into the sample port in order to take a sample of the fluid in the IV tube.
- When the fluid sampling system is configured as described above, a user, such as a doctor or nurse, can take a sample of a patient's bodily fluid, such as blood, by activating the fluid drawing device, which draws the bodily fluid into the IV tube past the sample port, allowing the user to access the bodily fluid at the sample port with the fluid sampling device. The fluid drawing device has a fill chamber through which the fluid from the IV tube can flow. Disposed within the fill chamber is a plunger that can be positioned between a first position and a second position. The plunger can be locked in the first and/or the positions. To activate the fluid drawing device, the user releases the locking mechanism on the plunger. Once the plunger is unlocked, the plunger can move toward the second position, thus creating a negative pressure in the IV tube, which draws the bodily fluid into the IV tube past the sample port. The user can then insert the fluid sampling device into the sample port to retrieve a sample of the bodily fluid. When a sufficient fluid sample has been retrieved, the fluid sampling device can be removed from the sample port and the user can depress the plunger of the fluid drawing device to force the extra bodily fluid back into the patient. The fluid sampling device can be configured to have a test strip disposed therein. When the bodily fluid enters the fluid sampling device from the sample port, the bodily fluid can be absorbed by the test strip. The sample of bodily fluid absorbed by the test strip can then be analyzed by a glucometer.
- As seen in
FIG. 1 , an exemplary embodiment of thefluid sampling system 50 can include anIV tube 102, afluid drawing device 100, asample port 126, and afluid sampling device 200 and/or 400.Fluid drawing device 100 is in fluid communication withIV tube 102 such thatfluid drawing device 100 can draw fluid throughIV tube 102past sample port 126. Afterfluid drawing device 100 has drawn fluidpast sample port 126,fluid sampling device sample port 126 to obtain a fluid sample. -
FIGS. 2A-2B illustrate an exemplary embodiment offluid drawing device 100. In this embodiment,fluid drawing device 100 comprises ahousing 140, apiston 142 partially disposed withinhousing 140, locking mechanism 150 connected topiston 142, acap 144 coupled to the top ofhousing 140, and aspring 146.Housing 140 offluid drawing device 100 is in fluid communication withIV tube 102 such that fluid flowing throughIV tube 102 flows from a first portion ofIV tube 102 throughhousing 140 and into a second portion ofIV tube 102. At the point of connection between the first portion ofIV tube 102 andhousing 140 there is afirst valve 160.First valve 160 is a one-way valve that allows fluid to flow from the first portion ofIV tube 102 intohousing 140. At the point of connection betweenhousing 140 and the second portion ofIV tube 102 there is asecond valve 162.Second valve 162 is configured to allow fluid to flow both into and out ofhousing 140. The direction of fluid flow throughsecond valve 162 is determined by the pressure in the system. In alternative embodiments, one or both of first andsecond valves IV tube 102 andvalves 162 can be made of a medical grade plastic and/or rubber. -
Cap 144 connects to the top portion ofhousing 140. Extending out fromcap 144 are cap handles 152. Cap handles 152 are sized and shaped to assist a user incompressing piston 142 into its first position, as seen inFIG. 2A .Cap 144 has at least one opening therein to allow portions ofpiston 142 and locking mechanism 150 to extend therethrough.Cap 144 is configured to restrict the movement ofpiston 142 such that the first end ofpiston 142 remains withinhousing 140. Coupled to a bottom surface ofcap 144 is asterility liner 164.Sterility liner 164 also couples to piston 142 (described below).Sterility liner 164 can be coupled to cap 144 andpiston 142 by any suitable means, such as clamps, O-rings, glue, and the like.Sterility liner 164 functions to prevent the interior ofhousing 140 from becoming contaminated. Whenpiston 142 is in the position illustrated inFIG. 2A , a portion of the interior ofhousing 140 is exposed. To prevent the interior walls ofhousing 140 from becoming contaminated,Sterility liner 164 is used to enclose at least a portion of the interior ofhousing 140 so as to prevent contamination of the interior walls ofhousing 140. Withoutsterility linter 164,housing 140 could become contaminated, which contamination would enter the fluid sampling system whenpiston 142 is moved to the position illustrated inFIG. 2B . Such contamination could expose a risk to a patient.Sterility liner 164 can be made of an air-impermeable material, such as a film of plastic. - A first end of
piston 142 is slidably disposed withinhousing 140. Extending around the edge of the first end ofpiston 142 is aseal 148.Seal 148 abuts the interior wall ofhousing 140, creating an airtight seal betweenpiston 142 andhousing 140 such that movement ofpiston 142 withinhousing 140 causes an increase or decrease in pressure withinhousing 140.Seal 148 can be an integral part ofpiston 142 or it can be a distinct piece adapted to be coupled to the first end ofpiston 142.Seal 148 can be made of a medical grade plastic and/or rubber. -
Piston 142 has arod 154 that extends from the first end ofpiston 142 and throughcap 144.Spring 146 is concentrically placed aroundrod 154. The first end ofspring 146 rests on the top ofcap 144.Rod 154 has arim 156 that extends over the second end ofspring 146, thus retainingspring 146 betweencap 144 andrim 156. Whenpiston 142 is moved from a second position (shown inFIG. 2B ) to the first position shown inFIG. 2 ,spring 146 is compressed betweenrim 156 andcap 144.Spring 146 thereforebiases piston 142 toward the second position shown inFIG. 2B relative to the first position shown inFIG. 2A . - In addition to
rod 154, extending from the first end ofpiston 142 is locking mechanism 150. In the example embodiment, locking mechanism 150 comprises twolevers piston 142 throughcap 144.Levers housing 140. Each oflevers notch 158 in an outer surface thereof that is sized and shaped to engagecap 144, thus preventing movement ofpiston 142 relative tohousing 140.Levers rod 154 to disengagenotches 158 fromcap 144, thus allowingpiston 142 to move relative tohousing 140. Whencap 144 engagesnotches 158,piston 142 is held in the position shown inFIG. 2A . As can be seen, even whenspring 146 is compressed and locking mechanism 150 is preventing movement ofpiston 142, there is sufficient space betweenhousing 140 and the first end ofpiston 142 to allow fluid to flow therethrough. - In use,
fluid drawing device 100 is connected toIV tube 102 andpiston 142 is locked in the down position illustrated inFIG. 2A . To draw fluid using the present exemplary embodiment offluid drawing device 100, a user activatesfluid drawing device 100 by compressinglevers piston 142 fromhousing 140. Whenpiston 142 is disengaged fromhousing 140,spring 146biases piston 142 upward to the position illustrated inFIG. 2B . Aspiston 142 moves upward withinhousing 140, a negative pressure is created inhousing 140 causingfirst valve 160 to close, preventing fluid from flowing from the first portion ofIV tube 102 intohousing 140. The negative pressure created inhousing 140 whenpiston 142 moves upward draws the fluid in the second portion ofIV tube 102 back intohousing 140.Spring 146 is designed to have sufficient travel and force to provide the necessary displacement to draw fluid, such as blood, from a patient into the second portion ofIV tube 102. As the fluid in the second portion ofIV tube 102 is drawn back intohousing 140, a negative pressure is created in the second portion ofIV tube 102, which in turn draws fluid from the patient's body back into the second portion ofIV tube 102past sample port 126. After the bodily fluid has been drawnpast sample port 126, the user can then insert the fluid sampling device (described in detail below) intosample port 126 to retrieve the desired fluid sample. The negative pressure inhousing 140 does not exceed that which is produced during regular phlebotomy by commonly used vacuum packed test tubes. After the fluid sample has been retrieved, the user can return the system to it original configuration (as seen inFIG. 2A ) by pressingpiston 142 back to its original position which re-infuses the patient's fluid into their body. Whenpiston 142 is depressed, locking mechanism 150 can be re-engaged and fluid flow through the system can be restored to its original rate. - The various components of the fluid drawing device can be made from a medical device industry standard, including, but not limited to thermoplastics, such as Polyethylene (PE), High Density Polyethylene (HDPE), Polypropylene (PP), Polystyrene (PF), Polyethylene Terephthalate (PET), and acrylic (for elements that are desired to be transparent, such as
chambers housing 140, for example), because of their low cost production, ability to be easily molded, sterility, and strength.Spring 146 can be made of steel or any other resilient metal or plastic material. It will be understood by one of ordinary skill in the art in view of the disclosure provided herein thatspring 146 can be a flexible member used to store mechanical energy. -
FIG. 3 illustrates an alternative exemplary embodiment of thefluid drawing device 100. Thefluid drawing device 100 comprises adriver plunger 104, the first end of which is disposed within adriver chamber 106. The first end ofdriver plunger 104 has adriver ridge 118 that sealingly engages the interior wall ofdriver chamber 106.Driver ridge 118 can be an integral part ofdriver plunger 104 or it can be a distinct piece adapted to couple to the first end ofdriver plunger 104. In either configuration,driver ridge 118 is adapted to create an airtight seal betweendriver plunger 104 anddriver chamber 106 such that movement ofdriver plunger 104 withindriver chamber 106 causes a corresponding change in pressure withindriver chamber 106.Driver ridge 118 can be made of a medical grade plastic or rubber. - The second end of
driver plunger 104 comprises adriver handle 122 which extends outside ofdriver chamber 106. The second end ofdriver plunger 104 also has alocking mechanism 114 disposed thereon.Locking mechanism 114 comprises at least one leaf spring type structure that extends away from a side ofdriver plunger 104 and that can engage an interior surface ofdriver chamber 106 to preventdriver plunger 104 from moving relative todriver chamber 106.Locking mechanism 114 can be compressed to disengagedriver plunger 104 fromdriver chamber 106, thus allowingdriver plunger 104 to move relative todriver chamber 106. When lockingmechanism 114 is engaged withdriver chamber 106, a space between the bottom ofdriver chamber 106 and the bottom surface ofdriver plunger 104 is created that is sufficient to allow fluid to flow therethrough. -
Fluid drawing device 100 also has afluid fill plunger 108, the first end of which is disposed within afluid fill chamber 110. The first end offluid fill plunger 108 has aridge 120 that sealingly engages the interior wall offluid fill chamber 110.Ridge 120 can be an integral part offluid fill plunger 108 or it can be a distinct piece adapted to couple to the first end offluid fill plunger 108. In either configuration,ridge 120 is adapted to create an airtight seal betweenfluid fill plunger 108 andfluid fill chamber 110 such that movement offluid fill plunger 108 withinfluid fill chamber 110 causes a corresponding change in pressure withinfluid fill chamber 110.Ridge 120 can be made of a medical grade plastic or rubber. - The second end of
fluid fill plunger 108 comprises a fluid fill plunger handle 124 which extends outside offluid fill chamber 110. Driver plunger handle 122 and fluid fill plunger handle 124 can be connected withconnector lock 116 so that the movement ofdriver plunger 104 andfluid fill plunger 108 is connected. When lockingmechanism 114 is engaged withdriver chamber 106, thus restricting movement offluid fill plunger 108 throughconnector lock 116, a space between the bottom offluid fill chamber 110 and the bottom surface offluid fill plunger 108 is created that is sufficient to allow fluid to flow therethrough. -
Driver chamber 106 andfluid fill chamber 110 are in fluid communication with each other and withIV tube 102. As can be seen inFIG. 3 , a fluid inIV tube 102 can flow throughdriver chamber 106, intofluid fill chamber 110, and on into a second portion ofIV tube 102. The second portion ofIV tube 102 has asample port 126 into which a user may insert afluid sampling device driver chamber 106 tofluid fill chamber 110, it passes throughflow gauge 112.Flow gauge 112 is a valve that regulates the amount of fluid that can pass fromdriver chamber 106 tofluid fill chamber 110, and thus into the patient.Flow gauge 112 can be adjusted by a user to allow a desired amount of fluid to pass fromdriver chamber 106 tofluid fill chamber 110. In the example embodiment,flow gauge 112 is configured to allow about 3 cc/hr to flow fromdriver chamber 104 tofluid fill chamber 110.Flow gauge 112 can also acts as a one-way valve to prevent fluid from flowing fromfluid fill chamber 110 todriver chamber 106. - As noted above,
fluid drawing device 100 can be connected inline withIV tube 102 which can be used for delivering a fluid, such as saline and/or a medicament to a patient. While fluid is being delivered to a patient throughIV tube 102,driver plunger 104 andfluid fill plunger 108 offluid drawing device 100 are in the positions illustrated inFIG. 3 . To retrieve a sample of bodily fluid usingfluid drawing device 100, a user activatesfluid drawing device 100 bycompresses locking mechanism 114 which disengagesdriver plunger 104 fromdriver chamber 106. The fluid pressure inIV tube 102 causesdriver plunger 104 to move up indriver chamber 106. Upward movement ofdriver plunger 104 reduces the pressure indriver chamber 106 causingflow gauge 112 to close, preventing fluid from flowing fromdriver chamber 106 tofluid fill chamber 110.Connector lock 116 causesfluid fill plunger 108 to move up simultaneously withdriver plunger 104. Asfluid fill plunger 108 moves up influid fill chamber 110, a negative pressure is created influid fill chamber 110 which draws the fluid in the second portion ofIV tube 102 back intofluid fill chamber 110. As the fluid in the second portion ofIV tube 102 is drawn back intofluid fill chamber 110, a negative pressure is created in the second portion ofIV tube 102, which in turn draws a bodily fluid, such as blood, from the patient back into the second portion ofIV tube 102past sample port 126. - After the bodily fluid has been drawn into
IV tube 102, the user can then insertfluid sampling device 200 or 400 (described in detail below) to retrieve the desired fluid sample. The negative pressure influid fill chamber 110 does not exceed that which is produced during regular phlebotomy by commonly used vacuum packed test tubes. Once the desired fluid sample is retrieved,fluid sampling device sample port 126. The user can then return the system to its original configuration by pressingfluid fill plunger 108 back to its original position which re-infuses the patient's bodily fluid into their body. The user can then press thedriver plunger 104 back to its original position and re-engagelocking mechanism 114. Once bothplungers flow gauge 112 opens and allows the system to deliver the desired amount of fluid to the patient. -
FIGS. 4A and 4B illustrate an exemplary embodiment of thefluid sampling device 200.Fluid sampling device 200 comprises ahandle 202, ablunt canula 204, and amain body 206 having an interior portion andwindows Blunt canula 204 is sized and shaped to fit within sample port 126 (seeFIG. 1 ).Blunt canula 204 has an opening in an end thereof that is in fluid communication with the interior portion ofmain body 206. The interior portion ofmain body 206 is adapted to hold a fluid sample, such as a blood sample.Windows main body 206 and allow a user to view the interior portion ofmain body 206.Windows fluid sampling device 200 with a thumb and forefinger. - In use, after
fluid drawing device 100 has been activated and a fluid has been drawnpast sample port 126,blunt canula 204 can be inserted intosample port 126. A small volume of fluid can be drawn through the blunt canula into the interior portion ofmain body 206 by pressure, such as hydrostatic, hemodynamic, and/or mechanically induced pressure.Windows Fluid sampling device 200 can then be removed fromsample port 126 and the fluid sample can be analyzed by a modified glucometer, as discussed below. -
FIGS. 5A-5D illustrate an alternative exemplary embodiment offluid sampling device 200. Similar to the previous embodiment,fluid sampling device 200 comprises ahandle 202, amain body 206, andwindows fluid sampling device 200 of the present embodiment comprises adiaphragm 208, avacuum chamber 210 disposed withinmain body 206, afirst channel 212, asecond channel 214, alure lock tip 216, and atesting compartment 218 disposed withinmain body 206. - As seen in the Figures,
adjacent handle 202, and disposed withinmain body 206, is avacuum chamber 210.Vacuum chamber 210 is defined bymain body 206 anddiaphragm 208.Diaphragm 208 is generally arch shaped and is made from a resilient, pliable material, such as rubber or plastic, so that a user can depressdiaphragm 208 to decrease the volume ofvacuum chamber 210.Vacuum chamber 210 is in fluid communication withfirst channel 212 such that when diaphragm 208 is depressed, air fromvacuum chamber 210 is expelled throughfirst channel 212.First channel 212 extends fromvacuum chamber 210 totesting compartment 218. -
Testing compartment 218 is disposed withinmain body 206 and is partially defined bywindows main body 206.Windows testing compartment 218 and determine when a sufficient sample of fluid has been obtained. Withintesting compartment 218 is anabsorbent material 220, such as foam, and atesting reagent 222.Absorbent material 220 absorbs and retains a fluid sample that is retrieved fromsample port 126 as described below.Testing reagent 222 is disposed adjacentabsorbent material 220 such that absorbed fluid will contacttesting reagent 222.Testing reagent 222 will react to various attributes of the fluid sample, such as glucose levels of a blood sample. -
Testing compartment 218 is in fluid communication withsecond channel 214.Second channel 214 extends throughlure lock tip 216 and opens at the end oflure lock tip 216.Lure lock tip 216 can be retrofitted with a blunt canula in order to access various applicable systems, such assample port 126. -
Fluid sampling device 200 of the present embodiment is used in a manner similar tofluid sampling device 200 of the previous embodiment. Whenfluid drawing device 100 has been activated and a fluid has been draw intoIV tube 102past sample port 126,fluid sampling device 200 can be used to retrieve a fluid sample fromsample port 126. The present example embodiment offluid sampling device 200 does not rely on hydrostatic or hemodynamic pressure to draw fluid fromsample port 126 intofluid sampling device 200. Rather, the present embodiment offluid sampling device 200 utilizes a negative pressure withinvacuum chamber 210 to draw fluid fromsample port 126 intofluid sampling device 200. Specifically, prior to insertinglure lock tip 216 intosample port 126, a user will depressdiaphragm 208 to expel air out ofvacuum chamber 210 throughfirst channel 212,testing compartment 218, andsecond channel 214, thus creating a potential vacuum withinvacuum chamber 210. Once the potential vacuum has been created invacuum chamber 210, lurelock tip 216, either as shown in theFIGS. 5A-5D or retrofitted with a blunt canula, is inserted into sample port 126 (seeFIG. 1 ). The user then releasesdiaphragm 208 to return to its original shape and position. Asdiaphragm 208 returns to its original position, a negative pressure or vacuum is created withinvacuum chamber 210.Vacuum chamber 210 anddiaphragm 208 are sized adapted to create a negative pressure withinfluid sampling device 200 sufficient to draw a desired quantity of fluid fromsample port 126, throughsecond channel 214, and intotesting compartment 218. - As the fluid enters
testing compartment 218,absorbent material 220 will absorb the fluid and distribute it acrosstesting reagent 222.Absorbent material 220 also functions to retain fluid withinfluid sampling device 200.Windows absorbent material 220 intesting compartment 218 to determine when an adequate fluid sample has been achieved. When a sufficient quantity of fluid has been drawn intotesting compartment 218, the user removesfluid sampling device 200 fromsample port 126. - Having obtained a fluid sample within
fluid sampling device 200, the fluid sample can then be analyzed using a modifiedglucometer 300 as seen inFIG. 7 . Glucometers are well known in the art. Atypical glucometer 300 comprises ahousing 302, a keypad 304, internal analysis apparatus 306 (not shown), and areceptacle 308 for receiving a test strip having a fluid sample, such as a blood sample, disposed thereon. The modified glucometer shown inFIG. 7 has a reconfiguredreceptacle 308 that is designed to receivefluid sampling device 200 therein.Receptacle 308 is adapted such that whenfluid sampling device 200 is inserted therein,windows glucometer 300. The analyzer light of modifiedglucometer 300 is directed through one or both ofwindows -
FIG. 6 illustrate yet another exemplary embodiment offluid sampling device 200.Fluid sampling device 200 of the present embodiment comprises handle 202,vacuum chamber 210,diaphragm 208,testing compartment 218, lurelock tip 216,channel 224,test strip 226,reagent 228, andvalves 230.Vacuum chamber 210 is in fluid communication withchannel 224 to allow air to be expelled fromvacuum chamber 210 throughchannel 224 when diaphragm 208 is depressed. Expulsion of air fromvacuum chamber 210 creates a potential vacuum therein. -
Fluid sampling device 200 is adapted to receive astandard test strip 226 disposed at least partially therein. In the illustrated embodiment,test strip 226 is received withintesting compartment 218,vacuum chamber 210 and handle 202.Fluid sampling device 200 can be adapted to receive standard supply test strips such as the SureStep Pro test strip made by LifeScan (a J&J subsidiary). -
Fluid sampling device 200 of the present embodiment is used in a manner similar to the previous embodiments offluid sampling device 200 equipped withdiaphragm 208. Specifically, a user depressesdiaphragm 208 to expel air out ofvacuum chamber 210 and create a potential vacuum therein.Lure lock tip 216, either as illustrated or retrofitted with a blunt canula, is inserted intosample port 126 anddiaphragm 208 is released to create a negative pressure withinvacuum chamber 210. The negative pressure withinvacuum chamber 210 draws fluid fromsample port 126 throughchannel 224 intotesting compartment 218. Fluid enteringtesting compartment 218 is absorbed bytest strip 226. Having received a sufficient fluid sample,fluid sampling device 200 can be removed fromsample port 126. - As seen in
FIG. 6 , unlike the previous embodiments offluid sampling device 200, handle 200 of the present embodiment can be removed to expose an end oftest strip 226. Handle 200 can be coupled tofluid sampling device 200 with the use of clamps, clips, or the like. Withhandle 202 detached fromfluid sampling device 200,test strip 226 can be removed fromfluid sampling device 200 for analysis of the fluid sample. By adaptingfluid sampling device 200 with aremovable handle 202, the fluid sample disposed ontest strip 226 can be analyzed using conventional means, such as a typical glucometer that is adapted to receive standard test strips. To prevent potential air leaks throughhandle 202 that would reduce the drawing force ofvacuum chamber 210 anddiaphragm 208,fluid sampling device 200 has one-way valve 230 disposed across the opening through whichtest strip 226 is inserted. -
FIG. 8 illustrates a perspective view of yet another embodiment offluid sampling device 400.Fluid sampling device 400 of the present embodiment comprises atop portion 402 and abase portion 404 that are adapted to be coupled together.Top portion 402 andbase portion 404 can be couple together in a first position and a second position. In the first position,fluid sampling device 400 can have atest strip 226 disposed betweenbase portion 404 and top portion 402 (as seen inFIGS. 8 and 11 ). It is contemplated that standard test strips, such as the SureStep Pro test strip made by LifeScan (a J&J subsidiary) can be used in combination withfluid sampling device 400.Top portion 402 is biased towardbase portion 404 such that whentest strip 226 is removedtop portion 402 moves towardbase portion 404.Fluid sampling device 400 can be configured for insertion withinsample port 126 to obtain a fluid sample as illustrated inFIG. 1 . In an alternative embodiment,top portion 402 can comprisetest strip 226. In this embodiment,base portion 404 andtest strip 226 can be coupled together with a flange, and adhesive such as glue, or a mechanical fastener. -
FIGS. 9A-9C illustrate end, side, and bottom views oftop portion 402. As seen in the Figures,top portion 402 comprises atop surface 406, abottom surface 408,flanges 410, andrecess 412.Top surface 402 defines anaperture 434 that can allow a user to view the interior offluid sampling device 400 to determine when a sufficient fluid sample had been obtained.Flanges 410 are disposed on opposing sides oftop portion 402 and extend frombottom surface 408. The ends offlanges 410 are rounded in toward the center oftop portion 402.Recess 412 is a cavity inbottom surface 408. The various elements oftop portion 402 can be integrally formed as a unitary piece, or the elements can be individually formed and then coupled together. As noted above,top portion 402 can comprisetest strip 226. -
FIGS. 10A-10C illustrate end, side, and bottom views ofbase portion 404.Base portion 404 comprises aplatform 414,walls 422, and ablunt canula 426.Platform 414 has abottom surface 420 and atop surface 416 withgrooves 418 therein as seen inFIG. 10C . The opposing ends 438 ofplatform 414 can function as handles to facilitate simple and convenient use offluid sampling device 400.Walls 422 are disposed on opposing sides ofplatform 414. The ends ofwall 422 are rounded in toward the center ofbase portion 404.Walls 422 havefirst ridges 424 andsecond ridges 428 extending along its outer surface. As seen best inFIG. 10A ,first ridges 424 are vertically abovesecond ridges 428 and extend further out thansecond ridges 428. Extending frombottom surface 420 isblunt canula 426.Blunt canula 426 has alumen 430 extending from a distal end ofblunt canula 426 through anaperture 436 inplatform 414. The distal end ofblunt canula 426 is adapted to be inserted intosample port 126 to obtain a fluid sample, such as a blood sample. -
FIG. 11 is a cross-sectional end view offluid sampling device 400 illustrating howtop portion 402 andbase portion 404 couple together. As noted above, the ends ofwall 422 andflanges 410 are rounded. The rounded ends ofwalls 422 andflanges 410 facilitate alignment oftop portion 402 andbase portion 404 and prevent horizontal movement oftop portion 402 relative tobase portion 404. The interior surfaces offlanges 410 each has an inwardly projecting ridge 432 that is adapted to engageridges top portion 402 is aligned withbase portion 404 andflanges 410 extend overwalls 422 and ridges 432 engageridges 424 whentest strip 226 is disposed betweentop portion 402 andbase portion 404.Top portion 402 is sized such that whentest strip 226 is in place and ridges 432 are engaged withridges 424,flanges 410 are deflected slightly away frombase portion 404. Whentest strip 226 is removed, the deflection inflanges 410 causestop portion 402 to be biased towardbase portion 404. Therefore, whentest strip 226 is removed,top portion 402 moves towardbase portion 404 untilbottom surface 408 oftop portion 402 comes into contact withtop surface 416 ofplatform 414. At this point, ridges 432 offlanges 410 engageridges 428 ofwalls 422. The engagement between ridges 432 and eitherridges 424 orridges 428 preventstop portion 402 from becoming undesirably separated frombase portion 404. In embodiments in whichtop portion 402 comprisestest strip 226,test strip 226 can be couple tobase portion 404 with a flange similar toflanges 410, ortest strip 226 can be bonded to base portion with a glue or plastic. - In use,
fluid sampling device 400 will havetest strip 226 inserted betweentop portion 402 andbase portion 404. Afterfluid drawing device 100 has been activated and a fluid has been drawn intoIV tube 102past sample port 126, a user can insert the distal end ofblunt canula 426 intosample port 126. Pressure, such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid fromsample port 126 to enterlumen 430 and move up throughbase portion 404 and ontotest strip 226. When a sufficient fluid sample has been obtained,fluid sampling device 400 can be removed fromsample port 126.Test strip 226 can then be withdrawn from betweentop portion 402 andbase portion 404 and analyzed in a glucometer as described above. In embodiments in whichtest strip 226 comprisestop portion 402,fluid sampling device 400 can be removed fromsample port 126 after a fluid sample has been obtained and a glucometer modified to receivefluid sampling device 400 can be used to analyze the fluid sample. In some embodiments in whichtest strip 226 comprisestop portion 402,test strip 226 can be removed frombase portion 404 and the fluid sample can be analyzed with a standard glucometer. - When fluid, such as blood, is drawn from
sample port 126 intofluid sampling device 400, excess fluid may be received withinfluid sampling device 400 and ontest strip 226. To prevent excess fluid from leaking out offluid sampling device 400 or remaining ontest strip 226 when it is removed fromfluid sampling device 400,top portion 402 hasrecess 412 andbase portion 404 hasgrooves 418 intop surface 416 that cooperate to eliminate these problems. Specifically,grooves 418 act like a squeegee to remove excess fluid fromtest strip 226 astest strip 226 is withdrawn fromfluid sampling device 400. Whentest strip 226 is removed fromfluid sampling device 400,top portion 402 andbase portion 404 come together as described above, andgrooves 418 andrecess 412 cooperate to retain the excess fluid withinfluid sampling device 400. -
FIG. 12 illustrates a perspective view of yet another embodiment of a fluid sampling device, generally denoted at 500.Fluid sampling device 500 of the present embodiment comprises atop portion 502 and abase portion 504 that are adapted to be coupled together in the same manner astop portion 402 andbase portion 404, as illustrated inFIG. 11 .Top portion 502 is identical totop portion 402 illustrated inFIGS. 9A-9C . Likewise,base portion 504 is similar tobase portion 404 illustrated inFIGS. 10A-10C . Also likefluid sampling device 400,top portion 502 andbase portion 504 are adapted to receivetest strip 226 therebetween. It is contemplated that standard test strips havingelectrical connections 236, such as the One Touch Ultra test strip made by LifeScan (a J&J subsidiary) or the Comfort Curve test strip made by Accu-Chek (a Roche subsidiary) can be used in combination withfluid sampling device 500.Fluid sampling device 500 can also be configured for insertion withinsample port 126 to obtain a fluid sample in the same manner asfluid sampling device 400 as illustrated inFIG. 1 . -
FIGS. 13A and 13B illustrate side and top views ofbase portion 504.Base portion 504 comprises aplatform 514,walls 522, and ablunt canula 526.Platform 514 has abottom surface 520 and atop surface 516 withgroove 518 therein as seen inFIG. 13B . The opposing ends 538 ofplatform 514 can function as handles to facilitate simple and convenient use offluid sampling device 500. Opposing ends 538 ofplatform 514 also haveretention walls top surface 516.Retention walls edges FIG. 12 ) to preventtest strip 226 from being removed from betweentop portion 502 andbase portion 504. In addition toretention walls test strip 226 can be coupled totop portion 502 and/orbase portion 504 with an adhesive such as glue, or a mechanical fastener. -
Walls 522 ofbase portion 504 are disposed on opposing sides ofplatform 514. The ends ofwall 522 are rounded in toward the center ofbase portion 504.Walls 522 havefirst ridges 524 andsecond ridges 528 extending along their outer surfaces.First ridges 524 are vertically abovesecond ridges 528 and extend further out thansecond ridges 528 in the same manner asfirst ridges 424 andsecond ridges 428 as illustrated inFIG. 10A .Walls 522 and first andsecond ridges base portion 504 totop portion 502 in a manner similar to that oftop portion 402 andbase portion 404 as illustrated inFIG. 11 . - Extending from
bottom surface 520 ofbase portion 504 isblunt canula 526.Blunt canula 526 has alumen 530 extending from a distal end ofblunt canula 526 through anaperture 536 inplatform 514. The distal end ofblunt canula 526 is adapted to be inserted into sample port 126 (FIG. 1 ) to obtain a fluid sample, such as a blood sample.Blunt canula 526 can also include a one-way valve 544 (not shown) to prevent or limit the reflux of air into theIV tube 102. In one embodiment,valve 544 is coupled to the distal end oflumen 530.Valve 544 can also be disposed in other positions withinlumen 530.Valve 544 can be made of a medical grade plastic and/or rubber. - In use,
fluid sampling device 500 will havetest strip 226 inserted betweentop portion 502 andbase portion 504. Afterfluid drawing device 100 has been activated and a fluid has been drawn intoIV tube 102past sample port 126, a user can insert the distal end ofblunt canula 526 intosample port 126. Pressure, such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid fromsample port 126 to enterlumen 530 and move up throughbase portion 504 and ontotest strip 226.Groove 518 is disposedadjacent aperture 536 andtest strip 226 to facilitate the escape of air fromtest strip 226, thus enabling the fluid sample to readily flow intotest strip 226. When a sufficient fluid sample has been obtained,fluid sampling device 500 can be removed fromsample port 126.Electrical connections 236 can then be inserted into a glucometer, such asglucometer 900 illustrated inFIG. 21 , for analysis. Glucometers, such asglucometer 900, are adapted to analyze various properties of the fluid sample absorbed bytest strip 226 by determining the electrical properties, such as the resistance, of the fluid sample. - When fluid, such as blood, is drawn from
sample port 126 intofluid sampling device 500, excess fluid may be received withinfluid sampling device 500 and ontest strip 226. In some embodiments it may be desirable to remove excess fluid fromtest strip 226. Groove 518 ofbase portion 504 can also be adapted to receive excess fluid received withinfluid sampling device 500. In the illustrated embodiment,groove 518 extends aroundaperture 536 to receive excess fluid that flows intofluid sampling device 500 throughlumen 530. It will be appreciated thatgroove 518 can comprise multiple concentric grooves, or any other configuration of one or more grooves that are adapted to receive excess fluid influid sampling device 500. -
FIG. 14 illustrates a perspective view of still yet another embodiment of a fluid sampling device, generally denoted at 600.Fluid sampling device 600 of the present embodiment comprises atest strip 226 and abase portion 604 that are adapted to be coupled together.Test strip 226 can be any one of a variety of test strips havingelectrical connections 236 or other means for analyzing properties of the fluid sample received byfluid sampling device 600. For example,test strip 226 could be a One Touch Ultra test strip made by LifeScan (a J&J subsidiary) or a Comfort Curve test strip made by Accu-Chek (a Roche subsidiary).Base portion 604 has a configuration similar tobase portions Fluid sampling device 600 can also be configured for insertion withinsample port 126 to obtain a fluid sample in the same manner as the previously discussed fluid sampling devices. -
FIG. 15 illustrates a top perspective view ofbase portion 604.Base portion 604 comprises aplatform 614, mountingportion 646, and ablunt canula 626.Platform 614 has abottom surface 620 and atop surface 616. Mountingportion 646 extends from a first end ofbase portion 604 to about the middle ofbase portion 604, and is generally defined by opposingside walls 648,end wall 650, andsupport surface 652.Support surface 652 hasgrooves 618 therein for receiving excess fluid in that same manner asgroove 518 offluid sampling device 500. Opposingside walls 648,end wall 650, andsupport surface 652 are adapted to abut edges oftest strip 226 such that the shape of mountingportion 646 corresponds to the shape oftest strip 226 so as to assist in maintainingtest strip 226 in a desired position. In addition,test strip 226 can be coupled tobase portion 604 with an adhesive such as glue, or a mechanical fastener. The opposing ends 638 ofplatform 614 can function as handles to facilitate simple and convenient use offluid sampling device 600. - Extending from
bottom surface 620 ofbase portion 604 isblunt canula 626.Blunt canula 626 has alumen 630 extending from a distal end ofblunt canula 626 throughaperture 636 insupport surface 652. In the illustrated embodiment,blunt canula 626 is offset toward one end ofplatform 614, however, it will be appreciated thatbase portion 604 can be configured withblunt canula 626 extending fromplatform 614 in other locations to accommodatevarious test strips 226. The distal end ofblunt canula 626 is adapted to be inserted into sample port 126 (FIG. 1 ) to obtain a fluid sample, such as a blood sample.Blunt canula 626 can also include a one-way valve 644 (not shown) to prevent or limit the reflux of air intoIV tube 102. In one embodiment, valve 644 is coupled to the distal end oflumen 630. Valve 644 can also be disposed in other positions withinlumen 630. Valve 644 can be made of a medical grade plastic and/or rubber. - In use,
fluid sampling device 600 will havetest strip 226 coupled tobase portion 604 within mountingportion 646. Afterfluid drawing device 100 has been activated and a fluid has been drawn intoIV tube 102past sample port 126, a user can insert the distal end ofblunt canula 626 intosample port 126. Pressure, such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid fromsample port 126 to enterlumen 630 and move up throughbase portion 604 and ontotest strip 226.Grooves 618 are disposedadjacent aperture 636 andtest strip 226 to facilitate the escape of air fromtest strip 226, thus enabling the fluid sample to readily flow intotest strip 226. When a sufficient fluid sample has been obtained,fluid sampling device 600 can be removed fromsample port 126.Electrical connections 236 can then be inserted into a glucometer, such asglucometer 900 illustrated inFIG. 21 , for analysis. Glucometers, such asglucometer 900, are adapted to analyze various properties of the fluid sample absorbed bytest strip 226 by determining the electrical properties, such as the resistance, of the fluid sample. - When fluid, such as blood, is drawn from
sample port 126 intofluid sampling device 600, excess fluid may be received withinfluid sampling device 600. In some embodiments it may be desirable to remove excess fluid received withinfluid sampling device 600 fromtest strip 226.Grooves 618 ofbase portion 604 can also be adapted to receive excess fluid received withinfluid sampling device 600. In the illustrated embodiment,grooves 618 extend parallel to each other on two opposing sides ofaperture 636 to receive excess fluid that flows intofluid sampling device 600 throughlumen 630. It will be appreciated thatgrooves 618 can comprise one or more grooves that extend around at least a part ofaperture 636. -
FIG. 16 illustrates a perspective view of still yet another embodiment of a fluid sampling device, generally denoted at 700.Fluid sampling device 700 of the present embodiment comprises atest strip 226 and abase portion 704 that are adapted to be coupled together.Base portion 704 has a configuration similar tobase portion 604.Fluid sampling device 700 can also be configured for insertion withinsample port 126 to obtain a fluid sample in the same manner as the previously discussed fluid sampling devices. -
FIGS. 17A and 17B illustrate top and bottom perspective views ofbase portion 704.Base portion 704 comprises aplatform 714, mountingportion 746, and ablunt canula 726.Platform 714 has abottom surface 720 and atop surface 716. Mountingportion 746 is generally defined by opposingside walls 748,end wall 750, andsupport surface 752.Support surface 752 hasgrooves 718 therein for venting air fromtest strip 226 as described below. Opposingside walls 748,end wall 750, andsupport surface 752 are adapted to abut edges oftest strip 226 to assist in maintainingtest strip 226 in a desired position. One or both ofside walls 748 can include a projectingportion 754 that extends toward the middle of mountingportion 746. In this manner, mountingportion 746 can be configured to fit around specific shapedtest strips 226, as illustrated inFIG. 16 . In addition,test strip 226 can be coupled tobase portion 704 with an adhesive such as glue, or a mechanical fastener. The opposing ends 738 ofplatform 714 can function as handles to facilitate simple and convenient use offluid sampling device 700. - Extending from
bottom surface 720 ofbase portion 704 isblunt canula 726.Blunt canula 726 has alumen 730 extending from a distal end ofblunt canula 726 throughaperture 736 insupport surface 752. In the illustrated embodiment,blunt canula 726 is offset toward one side ofplatform 714 to accommodatetest strip 226 as described below. However, it will be appreciated thatbase portion 704 can be configured withblunt canula 726 extending fromplatform 714 in other locations. The distal end ofblunt canula 726 is adapted to be inserted into sample port 126 (FIG. 1 ) to obtain a fluid sample, such as a blood sample.Blunt canula 726 can also include a one-way valve 744 to prevent or limit the reflux of air intoIV tube 102. In the illustrated embodiment,valve 744 is coupled to the distal end oflumen 730. It will be appreciated thatvalve 744 can also be disposed in other positions withinlumen 730.Valve 744 can be made of a medical grade plastic and/or rubber. Also disposed onbottom surface 720 arealignment members 756 which extend fromblunt canula 726 toward opposing ends ofplatform 714.Alignment members 756 provide a reference point to enable a user to center theblunt canula 726 in their fingers and to determine the center position of the offsetblunt canula 726.Alignment members 756 also add additional mass, and thus strength, tofluid sampling device 700. -
FIGS. 18A and 18B illustrate one example embodiment oftest strip 226 that can be used withfluid sampling device 700. The illustrated embodiment oftest strip 226 is a Comfort Curve test strip made by Accu-Chek (a Roche subsidiary). However,test strip 226 can be any one of a variety of test strips havingelectrical connections 236 or other means for analyzing properties of the fluid sample received byfluid sampling device 700, such as the One Touch Ultra test strip made by LifeScan (a J&J subsidiary). -
Test strip 226 includeselectrical connections 236,fluid intake 238, and vent 240. As discussed herein,electrical connections 236 can be used in conjunction with a glucometer to analyze the fluid sample retrieved withfluid sampling device 700.Fluid intake 238 can be an opening in the side, or other surface, oftest strip 226.Fluid intake 238 is adapted to receive a fluid sample, such as blood, therein. To enable a fluid to readily flow intofluid intake 238, the air disposed withinfluid intake 238 must be removed.Vent 240 is in fluid communication withfluid intake 238 and allows the air influid intake 238 to escape therefrom as a fluid sample enters fluid into 238. - In use,
fluid sampling device 700 will havetest strip 226 coupled tobase portion 704 within mountingportion 746. Afterfluid drawing device 100 has been activated and a fluid has been drawn intoIV tube 102past sample port 126, a user can insert the distal end ofblunt canula 726 intosample port 126. Pressure, such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid fromsample port 126 to enterlumen 730 and move up throughaperture 736 ofbase portion 704. The fluid sample then entersfluid intake 238 oftest strip 226. Air withinfluid intake 238 can escapetest strip 226 throughvent 240.Grooves 718 are disposedadjacent vent 240 to facilitate the escape of air fromtest strip 226 throughvent 240, thus enabling the fluid sample to readily flow intotest strip 226. When a sufficient fluid sample has been obtained,fluid sampling device 700 can be removed fromsample port 126.Electrical connections 236 can then be inserted into a glucometer, such asglucometer 900 illustrated inFIG. 21 , for analysis. Glucometers, such asglucometer 900 are adapted to analyze various properties of the fluid sample absorbed bytest strip 226 by determining the electrical properties, such as the resistance, of the fluid sample. - When fluid, such as blood, is drawn from
sample port 126 intofluid sampling device 700, excess fluid may be received withinfluid sampling device 600. In some embodiments it may be desirable to remove excess fluid received withinfluid sampling device 700 fromtest strip 226.Grooves 718 can also be adapted to receive excess fluid received withinfluid sampling device 700. In the illustrated embodiment,grooves 618 extend parallel to each other on two opposing sides ofaperture 636 to receive excess fluid that flows intofluid sampling device 600 throughlumen 630. It will be appreciated thatgrooves 618 can comprise one or more grooves that extend around at least a part ofaperture 636. - As with
fluid drawing device 100,fluid sampling devices -
FIG. 19 illustrates a perspective view of still yet another embodiment of a fluid sampling device, generally denoted at 800.Fluid sampling device 800 of the present embodiment comprises atest strip 226 and atest strip housing 802.Test strip housing 802 includes ablunt canula 826 and atest strip receptacle 804 for receiving at least a portion oftest strip 226 therein.Test strip 226 can be any one of a variety of test strips havingelectrical connections 236 or other means for analyzing properties of a fluid sample received byfluid sampling device 800. For example,test strip 226 could be a One Touch Ultra test strip made by LifeScan (a J&J subsidiary) or a Comfort Curve test strip made by Accu-Chek (a Roche subsidiary).Fluid sampling device 800 can also be configured for insertion withinsample port 126 to obtain a fluid sample in a manner similar to that of the previously discussed fluid sampling devices. - As illustrated in
FIGS. 19 and 20 ,test strip receptacle 804 has a generally flat, rectangular shape with aninterior portion 806.Interior portion 806 is adapted to receive at least a portion oftest strip 226 therein. In the illustrated embodiment,interior portion 806 is sized and configured to generally correspond to the size and shape oftest strip 226 such that an end oftest strip 226 can be inserted and maintained withintest strip receptacle 804.Test strip 226 can be held withininterior portion 806 oftest strip receptacle 804 by a variety of means, including frictional coupling, mechanical fasteners such as clamps or pins, and adhesives such as glue. In addition,test strip receptacle 804 can function as a handle to facilitate simple and convenient use offluid sampling device 800. - As can be seen in
FIG. 20 , the walls ofinterior portion 806 includegrooves 818 which provide similar functionality as the grooves described elsewhere herein. In particular,grooves 818 are adapted to assist in venting air fromtest strip 226 to enabletest strip 226 to readily absorb a fluid sample. In the exemplary embodiment,grooves 818 extend from the opening ofinterior portion 806 to about the opposing end oftest strip receptacle 804. However, it will be appreciated thatgrooves 818 can be otherwise configured. For example,grooves 818 can comprise a single groove orgrooves 818 can be completely disposed withintest strip housing 802. - Extending from an end of
test strip receptacle 804 is a connectingportion 808. Connectingportion 808 is generally funnel shaped and connectstest strip receptacle 804 toblunt canula 826.Blunt canula 826 has alumen 830 extending from a distal end ofblunt canula 826 throughaperture 836 in connectingportion 808.Test strip receptacle 804, connectingportion 808, andblunt canula 826 can be made from discrete parts and coupled together, such as with an adhesive, or they can be formed as a single integral piece. The distal end ofblunt canula 826 is adapted to be inserted into sample port 126 (FIG. 1 ) to obtain a fluid sample, such as a blood sample.Blunt canula 826 can also include a one-way valve 844 (not shown) to prevent or limit the reflux of air intoIV tube 102. In one embodiment, valve 844 is coupled to the distal end oflumen 830. Valve 844 can also be disposed in other positions withinlumen 830. Valve 844 can be made of a medical grade plastic and/or rubber. - In use,
fluid sampling device 800 will havetest strip 226 coupled withininterior portion 806 oftest strip receptacle 804. Afterfluid drawing device 100 has been activated and a fluid has been drawn intoIV tube 102past sample port 126, a user can insert the distal end ofblunt canula 826 intosample port 126. Pressure, such as hydrostatic, hemodynamic, or mechanically induced pressure, causes fluid fromsample port 126 to enterlumen 830 and move up throughblunt canula 826 and connectingportion 808 and ontotest strip 226.Grooves 818 are disposedadjacent test strip 226 to facilitate the escape of air fromtest strip 226, thus enabling the fluid sample to readily flow intotest strip 226. When a sufficient fluid sample has been obtained,fluid sampling device 800 can be removed fromsample port 126.Electrical connections 236 oftest strip 226 can then be inserted into a glucometer, such asglucometer 900 illustrated inFIG. 21 , for analysis. Glucometers, such asglucometer 900, are adapted to analyze various properties of the fluid sample absorbed bytest strip 226 by determining the electrical properties, such as the resistance, of the fluid sample. - While the foregoing exemplary fluid sampling devices have been illustrated and described as comprising multiple discrete parts that are coupled together, it will be appreciated that each of the various fluid sampling devices described herein can also be formed as a single integral piece. For example,
base portions test strip housing 802 can each be formed with an integrated test strip or other fluid monitoring technology. For example, the fluid sampling devices disclosed herein can be formed with an interior cavity or chamber which is in fluid communication with a blunt canula. A fluid monitoring device, such asabsorbent material 220 orelectrical connections 236, can be at least partially disposed within or in fluid communication with the cavity such that various attributes of the fluid sample can be detected without the use of a conventional test strip. - Having obtained a fluid sample within one of
fluid sampling devices glucometer 900 as seen inFIG. 21 . Glucometers are well known in the art. Atypical glucometer 900 comprises ahousing 902,keys 904, internal analysis apparatus 906 (not shown), and areceptacle 908 for receiving a test strip having a fluid sample, such as a blood sample, disposed thereon. The glucometer shown inFIG. 21 has areceptacle 908 that is designed to receive an end oftest strip 226 therein. Disposed withinreceptacle 908 are electrical connections (not shown) which are adapted for electrical communication withelectrical connections 236 oftest strip 226 when the end oftest strip 226 is inserted withinreceptacle 908. The internal analysis apparatus 906 ofglucometer 900 is adapted to analyze various electrical properties of the fluid sample received ontest strip 226. Such electrical properties can include the resistance, impedance, capacitance and the like of the fluid sample.Glucometer 900 is adapted to determine various attributes of the fluid sample, such as the glucose level of a blood sample, based on the electrical properties of the fluid sample. -
FIGS. 22A-22B illustrate an example embodiment of aprotective housing 1000 that is adapted to receive one offluid sampling devices protective housing 1000 is shown and described with specific reference tofluid sampling device 400. However, it will be appreciated thatprotective housing 1000 can be employed with any one offluid sampling devices - In the illustrated embodiment,
protective housing 1000 comprisessubstrate 1002, arailing 1008, and acover portion 1010.Substrate 1002 has atop surface 1004 and abottom surface 1006 that lays adjacenttop surface 406 oftop portion 402. Extending frombottom surface 1006 israiling 1008.Railing 1008 extends aroundfluid sampling device 400 and down to abouttop surface 416 ofplatform 414.Substrate 1002 andrailing 1008 can be formed as a unitary piece, or can be individually formed and coupled together. - Attached to the lower edge of
railing 1008 iscover portion 1010.Cover portion 1010 extends overblunt canula 426.Cover portion 1010 can comprise two layers of plastic 1010 a and 1010 b with air disposed therebetween. Layers of plastic 1010 a and 1010 b can be bonded together at various points to create pockets of air therein. As shown inFIG. 22B , layers of plastic 1010 a and 1010 b are bonded together nearrailing 1008 and the distal end ofblunt canula 426, thus creatingair pockets cover portion 1010 comprises a single layer of plastic 1010 a that extends fromrailing 1008 aroundbase portion 404. -
Protective housing 1000 is adapted to protectfluid sampling device 400 from physical damages prior to use, such as during shipment.Protective housing 1000 also maintains the sterility offluid sampling device 400 by preventing undesirable contamination through exposure to a non-sterile surface, such as a user's hands. -
Fluid sampling device 400 packaged inprotective housing 1000 is used in a manner similar to that described above with respect tofluid sampling device 400. However, whenfluid sampling device 400 is packaged inprotective housing 1000,cover portion 1010 must be ruptured prior to insertingblunt canula 426 intosample port 126. Typically, a user will holdfluid sampling device 400, disposed withinprotective packaging 1000, with their thumb or palm ontop surface 1004 ofsubstrate 1002, and their index and middle fingers extending around opposing sides ofcover portion 1010. Holdingfluid sampling device 400 andprotective housing 1000 in this manner, a user can squeezeprotective housing 1000 with enough force to ruptureair pockets air pockets blunt canula 426 can be forced through layers of plastic 1010 a and 1010 b to exposeblunt canula 426. Withblunt canula 426 exposed, a user can then insert blunt canula intosample port 126 to obtain a fluid sample in the same manner as previously described. - In some embodiments, one or both of layers of plastic 1010 a and 1010 b of
cover portion 1010 can be formed of a resilient material, such as a semi-rigid plastic, a shape memory material, a foam, or a rubber material. When employing aresilient cover portion 1010, a user can obtain a fluid sample in a manner similar to that described above (i.e., compresscover portion 1010 untilblunt canula 426 extends throughcover portion 1010 and insertblunt canula 426 into sample port 126). However, unlike the previously described embodiments, aresilient cover portion 1010 can regain its shape after the user removes pressure fromcover portion 1010. Ascover portion 1010 regains its original shape,blunt canula 426 is once again enclosed withincover portion 1010. Thus,protective housing 1000 can be configured so as to exposeblunt canula 426 when being inserted intosample port 126. Reducing the time thatblunt canula 426 is exposed, both before and after use, provides numerous benefits. As discussed above,protective housing 1000 can prevent contamination ofblunt canula 426 prior to use. Additionally, use of aresilient cover portion 1010 can also reduce the risk of exposure to a user, such as a nurse, by enclosingblunt canula 426, and any excess fluid thereon, withinprotective housing 1000. - As noted above, each of
fluid sampling devices protective housing 1000. As is readily apparent to one of ordinary skill in the art, various modifications can be made toprotective housing 1000 to accommodate various embodiments of fluid sampling devices. For example, whenprotective housing 1000 is utilized withfluid sampling devices bottom surface 1006 ofsubstrate 1002 laysadjacent test strip 226 andtop surface top portion substrate 1002 can also function to enclose the opening betweenaperture 736 andfluid intake 238 to assist in directing fluid received throughblunt canula 726 intofluid intake 238 oftest strip 226.Substrate 1002 can also assist in preventing fluid received withinfluid sampling device 700 from leaking out offluid sampling device 1000. - In one embodiment, the fluid drawing device can comprise a housing having a fill chamber in fluid communication with a patient injection site. A piston can be positionable within the fill chamber to sealingly engage the fill chamber, wherein the piston has a first position and a second position, wherein movement of the piston from the first position to the second position generates a negative pressure in the fill chamber effective to draw fluid from the patient injection site into the fill chamber. The fluid drawing device can also include biasing means for biasing the piston to the second position relative to the first position. The biasing means can comprise a spring linked to the piston, such that the spring is more compressed when the piston is in the first position than when the piston is in the second position. In some embodiments, the biasing means is generated by fluid pressure from the patient injection site. In other embodiments, the biasing means is generated by hydraulic actuation. The fluid drawing device can also include securing means for selectively securing the piston in the second position. The securing means can comprise a locking system at least partially coupled to the piston.
- In an alternative exemplary embodiment, the fluid drawing device can comprise a housing having a fill chamber in fluid communication with a patient injection site, a piston disposed and positionable within the fill chamber, the piston being sealingly engaged with the fill chamber to generate a negative pressure in the fill chamber effective to draw fluid from the patient injection site into the fill chamber when the piston is moved from a first position to a second position. The fluid drawing device can also include biasing means for biasing the piston to the second position relative to the first position, and securing means for selectively securing the piston in the first position. The biasing means of the fluid drawing device can comprise a spring linked to the piston, such that the spring is more compressed when the piston is in the first position than when the piston is in the second position. The biasing means can also be generated by fluid pressure from the patient injection site. The biasing means can also be generated by hydraulic actuation. The securing means can comprise a locking system at least partially coupled to the piston.
- In another alternative example embodiment, the fluid drawing device can comprise a housing having a fill chamber in fluid communication with a patient injection site, a piston positionable within the fill chamber to sealingly engage the fill chamber, wherein the piston has a first position and a second position, wherein movement of the piston from the first position to the second position generates a negative pressure in the fill chamber effective to draw fluid from the patient injection site into the fill chamber, a spring linked to the piston, wherein the spring is more compressed when the piston is in the first position than when the spring is in the second position, such that the spring tends to bias the piston to the second position relative to the first position; and a locking member coupled to the piston to selectively secure the piston in the first position. The locking member can be positionable to engage the housing to secure the piston in the first position. The locking member can be configured for selective disengagement from the housing so as to enable the piston to move between the first and the second positions.
- One embodiment, a method of sampling bodily fluid comprises: providing a fluid sampling system, wherein said fluid sampling system comprises an IV tube in fluid communication with a patient injection site, said IV tube having a sample port; a fluid drawing device in fluid communication with said IV tube, said fluid drawing device having a fill chamber and a piston sealingly engaged therein; and a fluid sampling device that is configured to be inserted within said sample port, said fluid sampling device having a blunt canula; drawing a fluid through said IV tube to sample port by activating fluid drawing device, wherein activation of said fluid drawing device comprises moving said piston relative to said fill chamber such that a negative pressure is generated in fluid drawing device sufficient to draw a fluid through IV tube to said sample port; and obtaining a fluid sample from said sample port by inserting said blunt canula into said sample port and drawing fluid into said fluid sampling device by hydrostatic or hemodynamic pressure, or negative pressure.
- In some embodiments of the method, the fluid drawing device comprises two fill chambers and two pistons. In some embodiments, the fluid drawing device further comprises a handle, a main body having an interior portion, and a window in the main body. In some embodiments the fluid drawing device is adapted to receive a test strip therein. In some embodiments the handle of the fluid drawing device is removable to facilitate removal of the test strip from the fluid drawing device. The fluid sampling device has an absorbent material disposed in the interior portion in some embodiments.
- In other embodiments, the fluid sampling device further comprises a base portion having a platform and a ridge extending around at least a portion of an outer surface of the base portion; and a top portion having a flange adapted to engage the ridge to couple the top portion to the base portion. In some embodiments, the fluid sampling device is adapted to receive a test strip between the base portion and the top portion. The fluid sampling device can be configured to allow the test strip to be removed from the fluid sampling device to facilitate analysis of the fluid sample.
- The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Claims (20)
1. A fluid sampling device comprising:
a blunt canula with a lumen extending therethrough;
a platform in fluid communication with said lumen of said blunt canula, said platform comprising a mounting portion having opposing retaining walls; and
a fluid monitoring device coupled to said mounting portion of said platform, said fluid monitoring device being in fluid communication with said lumen of said blunt canula.
2. The medical device of claim 1 , wherein said platform further comprises an aperture and a groove adjacent said aperture, said aperture being in fluid communication with said lumen of said blunt canula.
3. The medical device of claim 1 , wherein said fluid monitoring device comprises a test strip having electrical connections to facilitate analysis of a fluid sample received by said fluid sampling device.
4. The medical device of claim 1 , wherein said fluid monitoring device is coupled to said mounting portion of said platform with at least one of an adhesive and a mechanical fastener.
5. The medical device of claim 1 , wherein said fluid monitoring device is integrally formed with said platform.
6. The medical device of claim 1 , further comprising a housing that is adapted to protect from damage and prevent contamination of said blunt canula, said platform, and said fluid monitoring device, said housing comprising:
a substrate that lies adjacent said platform and said fluid monitoring device;
a railing extending from said substrate; and
a cover coupled to said railing, said cover substantially encloses said blunt canula to prevent contamination of said blunt canula prior to use.
7. The medical device of claim 6 , wherein said cover of said housing is formed of a resilient material adapted to extend around said blunt canula after use.
8. A method for sampling a bodily fluid, comprising the steps:
providing a fluid sampling device, said fluid sampling device comprising:
a blunt canula having a lumen extending therethrough, said blunt canula being adapted for insertion into a sample port of a central line;
a base portion in fluid communication with said blunt canula, said base portion comprising a mounting portion and an aperture, each of said mounting portion and said aperture being in fluid communication with said lumen of said blunt canula; and
means for detecting properties of a fluid sample coupled to said base portion at least partly within said mounting portion, said means for detecting being in fluid communication with said lumen of said blunt canula;
inserting said blunt canula into said sample port to create fluid communication between said central line and said lumen of said blunt canula to enable fluid within said central line to flow into said fluid sampling device; and analyzing the fluid sample received within said fluid sampling device.
9. The method of claim 8 , further comprising the step of drawing a bodily fluid into said central line prior to inserting said blunt canula into said sample port.
10. The method of claim 8 , wherein analyzing the fluid sample comprises associating said means for detecting properties of a fluid sample with a glucometer.
11. The method of claim 8 , wherein said base portion comprises a handle portion having an alignment member to facilitate alignment of said blunt canula with said sample port of said central line.
12. The method of claim 8 , wherein said means for detecting properties of a fluid sample comprises a test strip.
13. The method of claim 12 , wherein said mounting portion comprises opposing side walls and an end wall, said opposing side walls and said end wall being arranged to correspond to the shape of said test strip.
14. The method of claim 12 , further comprising a top portion adapted to be coupled to said base portion with said test strip disposed therebetween, said base portion having a retention wall to assist in maintaining said test strip in a desired position.
15. The method of claim 12 , wherein said test strip comprises a vent and said mounting portion comprises a groove, said vent and said groove cooperate to remove excess air from said test strip.
16. The method of claim 8 , wherein said blunt canula comprises a valve.
17. A medical device comprising:
a fluid sampling device adapted to be in fluid communication with a sample port of an intravenous tube, said fluid sampling device comprising:
a test strip adapted to receive a fluid sample;
a test strip receptacle having an interior portion adapted to receive at least a portion of said test strip therein; and
a blunt canula extending from an end of said test strip receptacle, said blunt canula having a lumen extending therethrough, said lumen being in fluid communication with said interior portion of said test strip receptacle and said test strip.
18. The medical device of claim 17 , wherein said test strip receptacle further comprises a groove adapted to assist in venting air from said test strip to enable said test strip to ready absorb a fluid sample.
19. The medical device of claim 17 , wherein a longitudinal axis of said blunt canula is generally parallel to a longitudinal axis of said test strip receptacle.
20. The medical device of claim 17 , wherein the test strip is coupled within said interior portion of said test strip receptacle with an adhesive.
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US13/030,012 US8216156B2 (en) | 2006-06-21 | 2011-02-17 | Systems, methods, and devices for sampling bodily fluid |
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US12/036,787 US20080255473A1 (en) | 2006-06-21 | 2008-02-25 | Systems, methods, and devices for sampling bodily fluid |
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US20110166433A1 (en) | 2011-07-07 |
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