Heart disease is a major public health issue of very high prevalence, especially in the Western world. Cardiac conditions include coronary artery disease, ischaemic heart disease, heart failure, valvular heart disease, cardiac arrhythmias and cardiac inflammation (myocarditis) to name a few. Coronary artery disease and heart failure are possibly the most serious and prevalent, together being a leading cause of death in the Western world. The impact of acute myocardial infarction and congestive heart failure and their sequelae on the quality of life of patients and the cost of health care drives the search for new therapies.
While there is continual discovery of new and efficacious compounds to treat heart disease, delivery of the active agent to cardiac tissue can be problematic. For example, the structure of many pharmaceuticals may be altered by the liver, destroying their therapeutic activity. Accordingly, systemic administration (i.e. by oral, IV, IM routes and the like) is often sub optimal. This problem has been overcome in part by using sublingual or rectal administration to avoid “first pass” degradation through the liver. However, after these routes of administration the drug can still be degraded on subsequent passes through the liver.
Another problem relates to toxicity of therapeutic agents. For example, a drug administered to target a tumor of the heart may have a toxic effect on healthy tissue in other parts of the body. Indeed, anticancer treatments are often discontinued due to toxicity problems, frequently leading to further progression of the cancer.
Another problem in the delivery of therapeutic agents to tissues of the heart arises where agents intended for treatment of the heart alone are lost to the systemic circulation where they are metabolized without benefit, or have a deleterious effect on other healthy tissues. In some cases, significant amounts of the therapeutic agent may be needed, and efficiency of the treatment is therefore reduced by loss of the agent to the general circulation and time of exposure to the heart tissue.
In United States Patent Application 20020062121 (Tryggvason et al.), there is exemplified a method for the delivery of gene therapy pharmaceuticals to the liver and lung of a mammal utilizing a closed perfusion system. While this document demonstrates some success in perfusing organs that have a comparatively simple vasculature, the document fails to disclose methods useful for delivering therapeutics to more complex organs.
It is an object of the present invention to overcome or alleviate a problem of the prior art by providing an improved method of isolating the cardiac circulation from the systemic circulation.
The discussion of documents, acts, materials, devices, articles and the like is included in this specification solely for the purpose of providing a context for the present invention. It is not suggested or represented that any or all of these matters formed part of the prior art base or were common general knowledge in the field relevant to the present invention as it existed before the priority date of each claim of this application.
FIG 1 is a simplified illustration of human heart showing some of the cardiac veins and arteries which make up the coronary circulation.
FIG 2 is a flow diagram illustrating steps performed in a method of isolating cardiac circulation according to an embodiment of the present invention.
FIG 3A illustrates a venous collection device having a support structure in the form of a frame for use with an embodiment of the invention.
FIG 5 illustrates a dye study demonstrating substantial isolation of the coronary circulation is achieved using the devices described herein. Vertical axis represents ICG (dye) concentration (pg/mL); horizontal axis represents time (minutes). Downward arrow represents time at which recirculation was stopped. Lines represent (from lightest to darkest shading) pulmonary artery, aorta, circuit arterial, circuit venous.
Briefly, a first aspect of the present invention provides a method for substantially isolating cardiac circulation from systemic circulation. Flow between the coronary sinus and the right atrium is occluded. A venous collection device having a collection lumen and a support structure is located in the coronary sinus. The support structure is used to maintain patency of the coronary sinus during collection of fluid through the collection lumen. An artificial flow path is provided between the collection lumen and the one or more coronary arteries. Using such method, during isolation of the cardiac circulation, cardiac pumping for systemic circulation is maintainable.
A second aspect of the present invention provides apparatus for substantially isolating cardiac circulation from systemic circulation. A first occluding means occludes flow between the coronary sinus and the right atrium. A support structure is provided which is locatable inside the coronary sinus and configured to maintain patency of the coronary sinus during collection of fluid therefrom. An artificial flow path connects fluid flow between a collection lumen in the coronary sinus and one or more coronary arteries. A delivery device is provided for delivering fluid from the artificial flow path to the one or more coronary arteries. Such isolation apparatus permits isolation of flow between the coronary sinus and the one or more coronary arteries from systemic circulation during cardiac contraction.
A third aspect of the present invention provides an occluding catheter for occluding flow between a main vessel and one or more branched vessels. The occluding catheter comprises a supply lumen and an inflatable body portion. The inflatable body portion is fed by the supply lumen and is configured to occlude flow between the main vessel and the one or more branched vessels. The inflatable body portion has an opening which, when the inflatable body portion is inflated, creates one or more first flow channels between the supply lumen and one or more branched vessels. The inflatable body portion is further configured to form, when inflated, a second flow channel permitting flow in the main vessel across the inflatable body portion in isolation from the first flow channel.
A fourth aspect of the present invention provides a method for delivering a therapeutic agent to the heart. Using the method, the cardiac circulation is substantially isolated from the systemic circulation by occluding flow between the coronary sinus and the right atrium and locating a support structure in the coronary sinus. The support structure maintains patency of the coronary sinus during collection of fluid therefrom. An artificial flow path is provided between the coronary sinus and the one or more coronary arteries. The therapeutic agent is added to the artificial flow path for delivery to the heart.
A fifth aspect of the present invention provides a percutaneously deliverable support structure for maintaining patency of the coronary sinus during collection of fluid therefrom. The support structure comprises two consecutively inflatable regions. The first region is configured to, when inflated, rest in abutment with a portion of the right atrium wall surrounding the coronary sinus ostium. The second region is configured to, when inflated, maintain patency of the coronary sinus while occluding flow between the coronary sinus and the right atrium.
A sixth aspect of the present invention provides a percutaneously deliverable support structure for maintaining patency of the coronary sinus during collection of fluid therefrom. The support structure comprises a three-dimensional framework which is deliverable to the coronary sinus in a compressed state. The framework is expandable upon release of the compressed structure from a delivery lumen to support the coronary sinus walls.
Delivering therapeutic agents to the heart for treatment of the heart tissue is more complicated than treatment of other organs because the heart must generate cardiac output as well as provide its own blood supply. Isolation of the heart's own blood supply from the systemic circulation is therefore desirable but challenging because of the potential variation between patients in cardiac vasculature, and the complex topography which has in the past deterred attempts at isolation.
Normally, four main coronary arteries provide oxygenated blood to the heart for distribution throughout the heart tissue; the left anterior descending (LAD), left circumflex (LC), left main (LM) and Right (R) coronary arteries. These are shown in the illustration of the heart provided in
Referring now to
The steps of occluding flow between the coronary sinus and the right atrium and positioning the venous collection device in the coronary sinus may be performed in sequence or substantially simultaneously. Where these steps are performed substantially simultaneously, the venous collection device may also be an occluding device.
During isolation of the cardiac circulation from the systemic circulation using the inventive method, it is important to maintain continuous circulation of fluid in the artificial flow path and in the cardiac circulation. Flow must be maintained to ensure delivery of blood (carrying oxygen and nutrients) to the cardiac tissue, and adequate delivery of therapeutic agents, if they are being administered.
In other organs, maintenance of desired flow rates during shunting of blood (e.g. in kidney dialysis) is relatively straightforward because the vessels through which access is gained are stiff and can withstand (a) insertion of collection catheters through the vessel wall, (b) occasional contact of the collection catheter tip with the vessel wall, and (c) negative pressures generated at the catheter tip during collection of fluid. In these cases, vessel collapse resulting from contact between the catheter tip and the vessel wall is rare, and not therefore of great concern during shunting procedures.
In contrast, the coronary sinus is significantly more difficult to deal with when attempting to collect fluid using a collection lumen located within the sinus. This is in part due to the fact that the coronary sinus wall is soft and conformable, unlike stiff artery walls, and is therefore prone to collapse when contacted by a collection catheter tip. This problem is intensified as a result of the negative pressures which may be generated at the catheter tip as fluid is drawn out of the sinus.
Further, because of the curvature of the coronary sinus, there is a natural tendency for a catheter tip approaching from the right atrium to contact the sinus wall, thus increasing the risk of collapse. Collapsing of the coronary sinus can cause venous pooling in the coronary veins and may therefore be fatal. Use of a venous collection device support structure to maintain patency of the coronary sinus, in accordance with the present invention, therefore minimizes the risk of these complications eventuating.
The venous collection device includes a collection lumen, an occluding body and a support structure which is configured to maintain patency of coronary sinus. Advantageously, the support structure also maintains the tip of the collection lumen substantially centrally, relative to the walls of the coronary sinus thereby further reducing the risk of the tip contacting the vessel wall. This is particularly important because, as briefly mentioned, a small negative pressure is established at the catheter tip as venous blood is drawn out of the sinus through the collection lumen. This negative pressure increases the risk of damaging the wall of the coronary sinus if contacted by the tip and also increases the risk of the collection lumen being occluded (i.e. by the vessel wall). Centralizing the collection lumen using the support structure significantly reduces the risk of invagination of the tip of collection lumen into the coronary sinus wall.
The venous collection device may be embodied in many different forms.
The venous collection device 310 of
In the embodiments illustrated in
It is to be understood that the support structure may be attached to or delivered within the collection lumen (as described above), or it may be provided as a separate component deliverable through a delivery catheter or sheath which may also deliver or position the collection lumen and/or occluding balloon. In such an embodiment, once the support structure is positioned in the coronary sinus, the delivery catheter/sheath is retracted relative to the support structure enabling it to expand and support the sinus walls to maintain patency. Centralization of the collection lumen tip is also achieved. The delivery catheter is then removed from the patient.
The venous collection device 320 illustrated in
The support structure 324 can be compressed or minimized for percutaneous delivery to the coronary sinus via a delivery catheter (not shown), as is the case for the devices illustrated in
Guide wires or other ancillary fibers/devices may aid in the positioning and expansion of the support structure. When the support structure is expanded, the silicon sheath or other flow-proof coating becomes taught, occluding flow between the sinus and the right atrium. Preferably, the rim of support structure 324 has a soft coating to minimize damage to the sinus wall. It is to be understood that the support structure 324 of
Preferably, the support structures 304, 314 and 324 of
To minimize the risk of blocking small veins which feed into the coronary sinus, the venous collection device should sit just inside the coronary sinus ostium, or be pressed against the ostium from the right atrium chamber. In either case, a hemodynamic seal is established. It is also desirable for the collection lumen 308 to be flexible for ease of delivery and positioning within the coronary sinus and to prevent vessel tenting.
The venous collection device 330 illustrated in
To deploy such a device, a guide wire (not shown) placed inside the coronary sinus guides the inflatable support structure into position. The first (proximal) region is inflated and a collection catheter extending therethrough is moved toward the coronary sinus ostium. Location of the ostium can be determined by deformation of the first (proximal) region. When the proximal region is inflated with a fluid which includes a contrast solution, radiographic imaging may be used. When in position, the second (distal) region is inflated to occlude flow between the sinus and the right atrium, maintaining patency of the sinus and centralizing the catheter tip for collection of fluid. This may be achieved by inflating two separate balloons or two conjoined inflatable balloon regions. The former requires incorporation of 3 lumens to enable (i) collection of fluid from the sinus; (ii) inflation of the first (proximal) balloon; and (iii) inflation of the second (distal) balloon whereas the latter requires only 2 lumens
In the embodiments illustrated in
Referring now to the particular embodiment illustrated in
The alternative support structure illustrated in
Alternatively, a valve or other suitable actuator may be used in place of membrane 356. Such valves may permit bi-directional control of flow between the first and second inflating bodies facilitating easy removal of the structure at the end of a procedure. In another embodiment, the dome of the bell may be folded upon itself onto the flange portion for percutaneous delivery to the coronary sinus. In such arrangement, a membrane or valve may not be necessary as adhesion between the folded layers may be sufficient to facilitate differential (consecutive) inflation of the two parts. The second inflating region may also include securing ribs, abrasions, spikes or the like, 343 to enhance stability of the support structure inside the sinus.
In dual balloon arrangement of the embodiments illustrated in
At the other end of the artificial flow path, a delivery device is positioned proximal the aortic valve to deliver blood (and agents) from the artificial flow path to the coronary arteries for circulation through the cardiac tissue.
In other embodiments, dilution of therapeutic agent may be undesirable so flow from the aorta into the coronary arteries should be prevented or at least minimized. Accordingly, it may be desirable for the delivery device to occlude flow between the aorta and the coronary arteries. In a similar manner to the positioning of the venous collection device in the coronary sinus, the steps of positioning the delivery device and occluding flow between the aorta and the one or more coronary arteries may be performed in two separate steps or substantially simultaneously. Where these steps are performed substantially simultaneously, the delivery device may also be an occluding device. To achieve isolation of the artificial flow path supplying the coronary arteries from the systemic circulation, an occluding catheter may be used.
An occluding catheter for occluding flow between a main vessel and one or more branched vessels has a supply lumen and an inflatable body portion fed by the supply lumen. When inflated, the inflatable body portion occludes flow between the main vessel (aorta) and the one or more branched vessels (coronary arteries). The inflatable body portion has an opening which, when the body portion is inflated, creates one or more first flow channels between the supply lumen and one or more branched vessels (coronary arteries). When inflated, the inflatable body portion also forms a second flow channel which permits flow in the main vessel (aorta) across the inflatable body portion in isolation from the one or more first flow channels.
Alternatively, the opening may extend around a substantial portion of the circumference of annulus 404 providing a flow path between the delivery lumen 408 and coronary arteries extending from the aortic sinus. In such an arrangement, the opening may therefore also supply accessory conal branches which exist in some patients ensuring more complete treatment of the cardiac tissue by any therapeutic agent which is introduced via the artificial flow path. The delivery device may provide two (as illustrated) or more openings 410 positioned around annulus 404 in such a way that each opening is used to establish a flow path to the left main (LM) and right (R) coronary arteries separately and to accessory branches if present via additional openings (not shown). When inflated, delivery device 400 also provides a systemic flow channel 406 through the center of the annulus 404. Systemic flow channel 406 enables the heart to generate and maintain cardiac output to the rest of the body while the cardiac circulation is isolated.
In use, the delivery device 400 is delivered percutaneously, in a deflated state (
It is desirable that the delivery device is sized appropriately to ensure a snug fit inside the aorta. Such snug fit minimizes leakage from the delivery lumen 408 into the aorta and substantially prevents flow from the aorta into the coronary arteries. In some cases this fit may be problematic because it impedes closure of the aortic valve leaflets. To address this issue, it is preferable that inflatable annulus 404 is contoured to prevent obstruction of valve closure. In such an embodiment, the delivery device further includes lobes 402 which correspond to each of the lobes of the aortic valve. Inclusion of the lobes enables the delivery device to be positioned snuggly inside the aortic valve whilst permitting valve closure.
A delivery device of the kind illustrated in
As an alternative to the delivery device of
Venous blood in the circulating solution will become oxygen depleted after supplying oxygen to the cardiac tissue. Therefore, it is desirable to include in the artificial flow path an oxygenation system, preferably of the kind normally incorporated into a cardiopulmonary bypass system or extracorporeal membrane oxygenation (ECMO) or equivalent. Using such a system, venous blood collected from the coronary sinus is oxygenated in the artificial flow path prior to it being re-circulated back into the heart. Therapeutic agent in the blood can also be replenished before re-circulation.
Means for circulating the blood solution in the artificial flow path (and through the cardiac tissue) may be provided in a range of different forms as would be appreciated by the skilled addressee. Such means may comprise a pulsatile or rotary pump incorporated into the apparatus to generate the required pressure head to circulate the blood. Such pressure is desired to be in the range 50 to 80 mmHg. To perfuse the blood/agent solution into the coronary arteries, the blood/agent solution should be drawn from the venous collection device at a suitable rate. It has been found that a rate of approximately 180 to 200 milliliters per minute may be suitable for most adults although flow rates as high as 250 milliliters per minute may be required. It is to be understood that this rate is not limiting (nor is the suggested pressure head), and may be adjusted according to the size, age and condition of the patient, and the nature of the apparatus and components used.
An auxiliary flow channel connected to a back-up reservoir may also be provided in the artificial flow path, to provide the requisite pressure head if constant flow at the desired rate cannot be achieved naturally. Alternatively, the auxiliary flow channel may draw blood from the right atrium to supplement the flow rate from the coronary sinus. Preferably, the artificial flow path includes means to monitor and adjust flow rates to ensure adequate supply to the coronary arteries. For example, where flow rates measured at the coronary sinus indicate that there is insufficient blood (and therapeutic agent) supply to the coronary arteries, a slow release valve may be activated which results in increased blood flow. This may also be in response to a negative pressure detected at the pump. The auxiliary flow channel enables more blood to enter the cardiac circulation with out compromising isolation of the therapeutic agent or other perfusate. The collection lumen and tip thereof should be sufficiently large to support the required flow rate.
Therapeutic agents and substances which may be added to the solution in the flow path may be selected from the group consisting of one or more of a virus, a pharmaceutical, a peptide, a hormone, a stem cell, a cytokine, an enzyme, a gene therapy agent, blood and blood serum. Advantageously, the present invention enables treatment of the heart tissue by gene therapy or the like, in the beating heart. Such treatment has not hitherto been achievable.
It is to be understood that while embodiments of the present invention have been described in the context of anterograde circulation and perfusion, it is to be understood that aspects of the invention may also be suitable for retrograde perfusion of the cardiac tissue and cells thereof.
The isolating cardiac circulation device was used to deliver a dye (ICG) to the heart, with the results shown in
The graph in
Finally, it is to be understood that various other modifications and/or alterations may be made to the parts described herein without departing from the spirit of the present invention outlined herein.
This application is a continuation-in-part application of International Application No. PCT/AU2005/000237, filed Feb. 23, 2005, which designated the United States, and which claims the priority benefit of U.S. Provisional Patent Application No. 60/612,846, filed Sep. 24, 2004, and U.S. Provisional Patent Application No. 60/548,038, filed Feb. 26, 2004, the content of which are hereby incorporated by reference. The present invention relates to the field of cardiology and more specifically to isolation of the cardiac circulation from the systemic circulation.
Number | Date | Country | |
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60612846 | Sep 2004 | US | |
60548038 | Feb 2004 | US |
Number | Date | Country | |
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Parent | 11510203 | Aug 2006 | US |
Child | 12803005 | US |
Number | Date | Country | |
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Parent | PCT/AU2005/000237 | Feb 2005 | US |
Child | 11510203 | US |