Patent Application
20110295214
The present invention relates to an injection device. More specifically, the present invention relates to an injection device for delivering fluid to an injection site, for example delivering cells into the walls of vessels in tissue.
It is known to use injection devices for subcutaneous injections. These devices conventionally comprise a housing and a syringe with a drive mechanism that moves the syringe into an extended position and which then ejects fluid from a needle connected to the syringe.
The problem with these conventional devices is that there has to be at least two independent actions. The syringe contains the fluid to be injected and this must first be moved within the injection device to extend the needle out of the injection device. The second action is the ejection of fluid from the needle once the syringe and needle have reached their extended positions. Having two separate actions makes the device complex and it is difficult to achieve accurate placement of the needle. This is particularly the case when injecting into locations that cannot be seen by the user, for example into walls of vessels or pathways, e.g. a vessel wall, in particular, into the wall of a track in an enterocutaneous fistula or into the rectal mucosa in the case of rectovaginal and perianal fistulas.
In general terms, a fistula is an abnormal connection or passageway between organs or vessels that normally do not connect. Fistulae can develop in various parts of the body. For example, types of fistulae, named for the areas of the body in which they occur, include anorectal fistula or fistula-in-ano or fecal fistula (between the rectum or other anorectal area and the skin surface), arteriovenous fistula or A-V fistula (between an artery and vein), biliary fistula (between the bile ducts to the skin surface, often caused by gallbladder surgery), cervical fistula (abnormal opening in the cervix), craniosinus fistula (between the intracranial space and a paranasal sinus), enteroenteral fistula (between two parts of the intestine), enterocutaneous fistula (between the intestine and the skin surface, namely from the duodenum or the jejunum or the ileum), enterovaginal fistula (between the intestine and the vagina), gastric fistula (between the stomach to the skin surface), metroperitoneal fistula (between the uterus and peritoneal cavity), perilymph fistula (a tear between the membranes between the middle and inner ears), pulmonary arteriovenous fistula (between an artery and vein of the lungs, resulting in shunting of blood), rectovaginal fistula (between the rectum and the vagina), umbilical fistula (between the umbilicus and gut), tracheoesophageal fistula (between the breathing and the feeding tubes) and vesicovaginal fistula (between the bladder and the vagina). Causes of fistulae include trauma, complications from medical treatment and disease.
It has become apparent that fistulae can be treated with an injection of stem cells. Cell populations and compositions that might be used are disclosed in Garcia-Olmo et al. (Int J Colorectal Dis 2003, 18:451-454) and Garcia-Olmo et al. (Dis Colon Rectum 2005, 48:1416-1423), and in the international patent applications published as WO 2006/037649, WO 2006/136244, WO 2007/039150 and WO 2007/065927.
Injection of stem cells into fistulae or into walls of vessels which are connected by fistulae requires very accurate placement of the injection needle to the target injection site. This is difficult to achieve when relying on a conventional syringe and plunger. Moreover, since the cells are being injected internally into tissue, it is difficult to achieve accurate placement via narrow delivery pathways without damaging the cells.
The present invention aims to solve the aforementioned problems.
It is an aim of the present invention to locate accurately a target injection site with an injection device and provide injection of an amount of fluid to the target injection site.
In a first aspect of the invention, there is provided an injection device comprising:
Preferably, the fluid container and discharge nozzle are in fluid communication with each other in the first extended position, in the first retracted position and in all positions therebetween.
Holding the fluid container stationary relative to the housing during use of the injection device provides a number of advantages. For example, extension of the needle and expulsion of a predetermined and fixed quantity of fluid can be achieved in a single continuous action which is smooth and which does not cause movement of the injection needle at the target injection site. Moreover, a single action means that the device is less complex and it is easier to achieve accurate placement of the needle. In addition, rather than having to move the entire syringe assembly to the target injection site, only the discharge nozzle, e.g. needle, is moved to the injection site which allows for much more accurate needle placement.
The injection device may further comprise a plunger, wherein the plunger is adapted to discharge fluid from the fluid container.
The injection device may further comprise a drive, wherein the drive is adapted to advance the discharge nozzle from its first retracted position to its first extended position. The drive may be adapted to act upon the plunger to expel fluid from the fluid container through the discharge nozzle.
Preferably, the drive is adapted such that only when the discharge nozzle has reached its first extended position, does the drive act upon the plunger to expel fluid from the fluid container through the discharge nozzle. This ensures that fluid is only delivered to a target injection site when the discharge nozzle, e.g. needle, has been extended sufficiently for injection of the fluid to take place.
Optionally, the drive is adapted to act upon the discharge nozzle and the plunger such that the discharge nozzle and plunger each move a predetermined distance in a single continuous motion. As mentioned above, having a single action makes the device less complex and it is easier to achieve accurate placement of the discharge nozzle and hence fluid.
Preferably, the plunger comprises a serrated ratchet.
The drive may comprise a first member and a second member, wherein the second member comprises a resiliently biased member adapted to engage the ratchet at a predetermined position of the drive relative to the housing. The fixed separation of the ratchet slots on the plunger provides for injection of a predetermined quantity of fluid each time the plunger is advanced from its retracted position. After each injection, the drive is withdrawn to its retracted position, whilst the plunger remains in the position it reached in the fluid container, ready to be further inserted to inject a further fixed quantity of fluid.
Preferably, the housing further comprises a first sleeve, wherein the discharge nozzle is contained within the first sleeve when in its first retracted position, and wherein the discharge nozzle extends from the first sleeve when in its first extended position.
Optionally, the housing comprises a second sleeve, wherein the second sleeve and the discharge nozzle are movable between a second retracted position in which the second sleeve and the discharge nozzle are contained within the first sleeve and a second extended position in which the second sleeve and the discharge nozzle extend from the first sleeve through an exit aperture in the first sleeve.
Preferably, when the second sleeve is in its second extended position, the discharge nozzle is movable between a third retracted position in which the discharge nozzle is contained within the second sleeve and its first extended position in which the discharge nozzle extends from the second sleeve through an exit aperture in the second sleeve. The second sleeve is moveable relative to the discharge nozzle so that there is an indication on whether or not the discharge nozzle has been inserted into tissue. If it has, injection can take place. This is achieved because the sliding sleeve does not enter tissue when the discharge nozzle is extended if tissue is present and impedes the movement of the sleeve, whereas the discharge nozzle can pass into the tissue, thereby extending beyond the end of the second sleeve. The relative displacement of the second sleeve and discharge nozzle can then be detected to give an indication of whether the discharge nozzle has entered tissue. Alternatively, the second sleeve can be connected to a locking mechanism which prevents fluid being expelled from the fluid container.
The injection device may comprise a biasing means that is adapted to couple the second sleeve to the drive.
The injection device may comprise a releasable stop means for releasably stopping the plunger after it has been moved a predetermined distance.
Optionally, the releasable stop means comprises a serrated member for interlocking with the serrated ratchet. Advantageously, the stop means is moveable on application of force by a user between an engaged position in which it engages with the serrated ratchet, preventing movement of the ratchet towards the proximal end of the injection device, and a disengaged position in which the stop means does not engage with the serrated ratchet, thereby permitting the plunger to be withdrawn towards the proximal end of the injection device. Even in its engaged position, the plunger can still move towards the distal end of the injection device, but cannot move towards the proximal end. This means that the plunger is maintained in a fixed position within the fluid container after a predetermined quantity of fluid has been ejected. Retraction of the drive and discharge nozzle does not result in the plunger being moved. This way, the injection device can be moved to another target injection site for injection of a further predetermined quantity of fluid.
Preferably, the fluid container comprises a cannular body, a flange at one end of the body and a discharge nozzle at a distal end of the body.
The injection device may comprise a flexible fluid pathway between the fluid container and the discharge nozzle. Preferably, the flexible fluid pathway is located adjacent to the fluid container. The flexible pathway may be adapted to straighten and bend, or extend and contract such that the discharge nozzle is movable between its first retracted position and its first extended position. The flexible fluid pathway may be manufactured as a coil of hollow tubing, advantageously a helical coil, which can extend and contract as the discharge nozzle moves relative to the fluid container. The coil may be formed from a metal, advantageously a resilient, flexible metallic material.
Preferably, the injection device comprises a connection element between the discharge nozzle and the drive, or between the flexible fluid pathway and the drive, such that when the drive is activated the discharge nozzle moves from its first retracted position to its first extended position.
Optionally, a stop means is provided for stopping the drive.
Preferably, the first sleeve comprises a cannular catheter.
Preferably, the drive comprises a depressible button.
Preferably, when the discharge nozzle has reached its first extended position, it continues to extend a predetermined distance as the drive is moved.
Preferably, when the discharge nozzle is at its first extended position, the discharge nozzle is at an angle to the first sleeve. In this way, the discharge nozzle is flexible so that it can exit the first sleeve at a plurality of points along the first sleeve.
Advantageously, it is easier to achieve accurate placement of the needle when the needle is flexible.
Optionally, a distal end of the first sleeve comprises an aperture and a suture anchor.
In a second aspect of the present invention, there is provided an injection device comprising:
Preferably, the injection device comprises an indicator which is viewable by a user of the injection device and which is adapted to indicate that fluid can be ejected from the fluid container only when the sleeve has moved the predetermined distance.
Alternatively, the injection device comprises a locking mechanism which is connected to the sleeve and drive and which is adapted to permit the drive to be moved to eject fluid from the fluid container only when the sleeve has moved the predetermined distance. In this way, ejection of the fluid will not place when the discharge nozzle is located in a cavity and not in tissue.
Preferably, the sleeve and discharge nozzle move relative to each other only when the sleeve and discharge nozzle come into contact with tissue, such that the discharge nozzle enters the tissue and the sleeve does not enter the tissue. In this way, ejection of fluid will only take place when the discharge nozzle has entered the tissue.
Preferably, the discharge nozzle is a needle and/or the fluid container is a syringe.
The discharge nozzle preferably has an internal diameter which is no less than (i.e. greater than or equal to) 0.4 mm along its length, or more preferably no less than (i.e. greater than or equal to) 0.5 mm along its length and advantageously may be no less than (i.e. greater than or equal to) 0.6, 0.7, 0.8, 0.9 or 1.0 mm along its length. Such a diameter is advantageous in preventing breakage of cells which might be injected from the injection device. Cells ejected from nozzles having smaller diameters than 0.5 mm, run the risk of being damaged by the increased pressure through the nozzle due to the reduced diameter and the friction between the cells and the internal wall of nozzle. The outer diameter of the needle is preferably greater than or equal to 0.9 mm, more preferably greater than or equal to 1.5 mm.
In a third aspect of the present invention, there is provided a kit, comprising the injection device of any one of claims 1 to 33 and a fluid container comprising a population of cells.
In one embodiment of the present invention, the fluid container comprises a population of human or animal cells. In another embodiment of the present invention, the fluid container comprises a population of stem cells.
Preferably, the cells are present in the fluid container in the form of a composition comprising the cells and a pharmaceutically acceptable carrier or excipient.
One or more embodiments of the present invention are described below with reference to the accompanying drawings, in which:—
a shows a further top plan view of the injection device of
a is an enlarged side view of a section of the injection device of
b is a further enlarged side view of a section of the injection device of
a is a perspective view of an enlarged section of a catheter of the injection device of
b is a cross-sectional view of the catheter of
c is a further cross-sectional view of the catheter of
d is a further cross-sectional view of the catheter of
With reference to
The injection device 100 comprises a housing 102 and a channel 104 that is shaped and dimensioned to receive a plunger 106. The channel 104 comprises an end wall 108 at the proximal end 100a for restricting movement of the plunger 106 out of the proximal end of the channel 104. At its distal end, the channel is open to provide a pathway to the syringe 120. The plunger 106 sits in the channel and can slide into an open end of the syringe 120 to act on a bung 119 in the syringe 120.
The plunger 106 comprises a serrated ratchet 110 which comprises a plurality of teeth 112 which are spaced apart from each other by a predetermined distance. The plunger 106 further comprises an end member 116, in the form of a projection which extends out of the channel 104. The end member 116 is for use by a user to locate the plunger 106 in a desired start position within the channel 104 and syringe 120 and for relocating the plunger 106 to its start position. The start position is defined as the position in which the plunger 106 is first positioned by a user to act on fluid in the syringe 120 when a new syringe 120 is inserted into the device 100.
The housing 100 has a slot 118 adjacent to the channel 104 towards the distal end 100b of the injection device 100. The slot 118 is shaped and dimensioned to receive a fluid container, in the present embodiment in the form of a syringe 120. The slot 118 is further shaped and dimensioned to hold the syringe 120 stationary during use of the injection device 100. The syringe 120 comprises a cannular body 122, a flange 123 and an opening dimensioned to receive the plunger at a proximal end 100a of the body 122, and a nozzle 124 at the distal end 100b of the body 122.
A sleeve is connected to the distal end 100b of the housing 102 in the form of a hollow catheter 126. The catheter 126 is shaped and dimensioned internally to receive an elongated discharge nozzle in the form of a needle 128 (not shown). The catheter 126 has an aperture 138 at its distal end 100b through which the needle 128 projects when moved to an extended position. In a retracted position, the needle 128 does not project from the aperture 138. The distal end of the catheter 126 also comprises a recess/suture anchor 140 in the form of a hole through the catheter 126 for use in suturing. The syringe 120 and the needle 128 are fluidly connected to each other by a flexible fluid pathway. The fluid pathway is described in more detail below in connection with
The housing 102 also comprises gripping means, in the form of a pair of ears 132 which are positioned on an outer surface of the housing 102. Each ear 132 has an aperture 132a which is shaped and dimensioned to enable a user to grip the injection device 100 by placing one of the index and middle finger of one hand through a respective aperture 132a.
A drive 134 is located at the proximal end 100a of the injection device adjacent to the channel 104. The drive 134 is connected to the needle 128 as will be explained below. The drive 134 is actuated by means of a depressible button 136 which can be pressed by a user's thumb on the same hand as his middle and index fingers when each is inserted through a corresponding aperture 132a.
As can be seen in
As can be seen in
a and 4b show in more detail how the syringe 120 is connected to the needle 128 at the distal end of the device 100b. The nozzle 124 tapers into a male luer 160. The male luer 160 is connected to the needle 128 in the catheter 126 via the flexible fluid pathway 150. The flexible fluid pathway 150 is connected to the needle 128 by way of a skive 168 in the catheter 126.
The flexible fluid pathway 150 is adapted to straighten and bend, or extend and contract such that the needle 128 is movable between its retracted position and its extended position. The needle 128 is also flexible or semi-rigid so as to bend through the catheter 126 out of the aperture 138. The needle 128 and flexible fluid pathway 150 are integrably formed with each other. The needle 128 and the flexible fluid pathway are manufactured from PEEK coated fused silica. As PEEK coated fused silica is not as strong as steel, the outer diameter of the needle 128 will be larger than the standard gauge size, for example 1.5 mm rather than 0.91 mm in a 20 Gauge needle. It is also envisioned that the internal diameter of the needle may be 0.53 mm. This is between the 20 Gauge (0.61 mm) and 22 Gauge (0.41 mm) internal diameter that is used in conventional needles. A connection element (not shown) is located between the needle 128 and the drive 134, or between the flexible fluid pathway 150 and the drive 134, and integrated with them such that when the drive is activated the needle 128 moves from its retracted position to its extended position.
In use, the injection device 100 containing fluid to be injected into a target injection site is placed in a desired location by an operator. For example, this might include placing the catheter 126 inside the rectum and into a fistula tract. Once in the desired location, the button 136 at the proximal end 100a of the injection device 100 is pushed towards the distal end 100b causing the first 144 and second 146 drive members to move. As the first drive member 144 moves, it will cause the needle 128 to move towards the distal end 100b from its retracted position in which the needle 128 is contained within the catheter 126 to its extended position in which the needle 128 has moved relative to the syringe 120 and extends from the catheter 126 through the aperture 138 into tissue. As the second drive member 146 moves, the retainer 147 prevents the second drive member 146 from engaging with the serrated ratchet 110 for a first predetermined distance D1.
Once the drive 134 has moved the first predetermined distance D1, the needle 128 will be in its extended position and the second drive member 146 will no longer be prevented from engaging with the serrated ratchet 110. As the drive 134 continues to move from a first predetermined position to a second predetermined position, the second drive member 146 engages with a least one tooth 112 of the serrated ratchet 110 causing the plunger 106 to move a predetermined distance D2 from a start position along the channel 104 in the syringe 120 which in turn causes the bung 119 of the syringe 120 to move into the syringe 120 to expel a predetermined volume of the fluid into the target injection site. Once the drive 134 has moved the second predetermined distance D2, the stop 148 stops the drive 134 from ejecting more fluid than that which is set by the second predetermined distance D2. The stop member 142 automatically engages with the serrated ratchet 110 on the plunger 106, preventing movement of the ratchet 110 towards the proximal end 100a of the injection device 100.
In preparation for the next injection, the button 136 is pulled back towards the proximal end 100a which causes the needle 128 to return to its retracted position. The injection device 100 is now ready to deliver another predetermined volume of fluid. However, because the stop member 142 stops the plunger 106 from moving when the button 136 is pulled back towards the proximal end 100a, the plunger 106 is maintained at the predetermined distance D2 from its previous start position. The above-described steps of injecting predetermined volumes of fluid can be repeated until the syringe 128 has expelled its last remaining predetermined volume of fluid. At this time, or when injections for a particular patient have been completed, the stop member 142 can be actuated to release it from the plunger 106, thereby permitting the plunger 106 to be retracted out of the syringe 128. The syringe 120 can then be replaced or refilled and the plunger 106 can be relocated to its start position so that the injection device 100 is ready to inject a predetermined amount of fluid once more.
a to 5d show a particular embodiment of needle 128 and catheter 126 of the injection device 100 of the present invention.
a shows a perspective view of the end of the catheter 126 with the aperture 138 which allows the needle 128 and a feeler tube 162 to pass though.
b is a cross-section of the catheter 126 of
When the button 136 is pressed, the needle 128 will advance as described above in connection with
As can be seen in
d shows advancement of the needle 128 where the needle 128 is located in a cavity 166 in the tissue 164. As opposed to the operation of the injection device 100 in
It will of course be understood that the present invention has been described above purely by way of example and modifications of detail can be made within the scope of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 0809361.9 | May 2008 | GB | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/IB2009/005827 | 5/21/2009 | WO | 00 | 8/17/2011 |
