阅读说明：本技术 体外生命支持系统 (In vitro life support system ) 是由 林筱倩 陆鹏举 于 2017-07-12 设计创作，主要内容包括：本发明提供了一种方法,系统和装置,可以显着地降低临床使用单腔室导管于双部位插管方式的静脉-静脉型体外膜氧合(Venovenous Extra-CorporealMembrane Oxygenation,VV ECMO)的再循环现象(Recirculation)。主动控制的流量调节器包括有球囊、阻塞器和储血器,这些单元可以单独地或共同地被装配在引流导管(Drainage Cannula)或灌流导管(Infusion Cannula)上,或者在两种导管上都装配,来实现使VV ECMO体外循环支持功效达到最高的目标。本发明介绍三个具体实施例来说明所提出以心律作参考而进行血流控制的实际实施情形,以实现大量地减少高氧合血流再循环回到VV ECMO回路的目的。(The present invention provides a method, system and apparatus that significantly reduces the Recirculation (Recirculation) of veno-venous extracorporeal Oxygenation (VV ECMO) in a dual site intubation mode using a single-lumen catheter in the clinic. Actively controlled flow regulators, including balloons, occluders and reservoirs, can be mounted on either or both of a Drainage catheter (Drainage Cannula) and Infusion catheter (Infusion Cannula) individually or collectively to maximize the VV ECMO extracorporeal circulation support efficacy. The present invention introduces three embodiments to illustrate the practical implementation of the proposed cardiac rhythm-referenced blood flow control for the purpose of substantially reducing the recirculation of highly oxygenated blood flow back to the VV ECMO loop.)

1. An in vitro life support system, comprising:

a blood pump and an oxygenator disposed outside the patient's body;

a perfusion catheter assembly disposed in a superior or inferior vena cava for perfusion of oxygenated blood, comprising at least one of a perfusion end balloon actuated according to a patient's heart rhythm, a perfusion end occluder and a perfusion end reservoir, wherein the perfusion end balloon is inflated or deflated to control venous return blood, the perfusion end occluder is compressed or deflated to control blood flow perfused to a right atrium of the patient, the perfusion end reservoir is actuated with the perfusion end occluder to maintain continuous blood pump flow; and

a drainage catheter assembly disposed opposite the infusion catheter assembly and disposed in the superior vena cava or inferior vena cava, the drainage catheter assembly for receiving hypoxic blood combination from venous return.

2. The in vitro life support system of claim 1, wherein the perfusion catheter assembly comprises a single chamber catheter, a perfusion end occluder and a perfusion end blood reservoir arranged in series to minimize flow resistance, wherein perfusion flow is regulated by compressing or expanding the cross-sectional area of the perfusion end occluder in combination with a passive perfusion end blood reservoir to react to perfusion end occluder movement to maintain continuous operation of a blood pump in the life support system.

3. The in vitro life support system of claim 1, wherein the patient's heart rhythm is derived from an electrocardiographic signal.

4. An in vitro life support system, comprising:

a blood pump and an oxygenator disposed outside the patient's body;

a drainage catheter assembly disposed in a superior vena cava or an inferior vena cava for receiving hypooxygenated blood, comprising at least one assembly of a drainage end balloon actuated according to a patient's heart rhythm, a drainage end occluder and a drainage end reservoir, wherein the drainage end balloon is inflated or deflated to control venous return blood, the drainage end occluder is compressed or relaxed to control blood flow drawn into the extracorporeal life support system, and the drainage end reservoir is actuated with the drainage end occluder to maintain continuous blood pump flow; and

an infusion catheter assembly disposed relative to the drainage catheter assembly and disposed in the superior or inferior vena cava to infuse hyperoxygenated blood from the life support system, comprising at least one of an infusion end balloon actuated according to the patient's heart rhythm, an infusion end occluder and an infusion end blood reservoir, wherein the infusion end balloon is inflated or deflated to control venous return blood, the infusion end occluder is compressed or deflated to control blood flow infused to the right atrium of the patient, the infusion end blood reservoir is actuated with the infusion end occluder to maintain continuous blood pump flow; and the drainage and perfusion catheter assemblies are operated together in an optimal manner to perfuse a maximum amount of highly oxygenated blood into the right ventricle during diastole and to reduce highly oxygenated blood recirculation back to the life support circuit during systole.

Technical Field

The present invention relates to an extracorporeal life support system, which primarily uses an actively controlled flow regulation method in the Venovenous Extra-cardiac Membrane Oxygenation (VV ECMO) system, preventing recirculation of oxygenated blood back into the ECMO circuit via the drainage catheter. Specifically, the present invention uses an Electrocardiographic (ECG) signal as a reference for actively controlling the actuation control time of the flow regulation system to further improve the recirculation phenomenon by retarding or accelerating the flow in the conduit. The aim is to allow maximum flow of highly oxygenated blood into the right ventricle at diastole, when the tricuspid valve is open; when the heart contracts and the tricuspid valve closes, the high oxygen blood in the ECMO circuit is reduced to be perfused into the right atrium and the vena cava, but simultaneously, the low oxygen blood in the human body can be reflowed back to the ECMO circuit in a large amount.

Background

Since the pandemic of avian influenza in 1992, the extracorporeal membrane oxygenation (ECMO) system was used worldwide to rescue serious Respiratory diseases such as Acute Respiratory Distress Syndrome (ARDS), the usage of which was escalating. Currently, about 40% of annual ECMO use is associated with the treatment of acute respiratory distress syndrome or other severe respiratory diseases, where intubation methods and design are critical to how effectively lung disease is treated.

ECMO is generally classified into venous-arterial ECMO (va ECMO) and venous-venous ECMO (vv ECMO) intubation types. Clinically VA ECMO is used for the treatment of heart failure patients, while VV ECMO is used for the treatment of respiratory failure patients. The extracorporeal pulmonary circulation circuit of VV ECMO derives from the use of a single-chamber catheter cannulated at two sites, most commonly a drainage catheter inserted in the Inferior Vena Cava (IVC) and a perfusion catheter inserted in the Superior Vena Cava (SVC), respectively. The most common VV ECMO model involves a drainage catheter that is tunneled and advanced into the inferior vena cava, and a perfusion catheter that is advanced into the superior vena cava after insertion into the jugular vein, with the two catheters finally converging near the Right Atrial (RA) region. Because the tips of the drainage catheter and the perfusion catheter are in close proximity, a significant portion of the hyperoxygenated blood in the perfusion catheter is drawn into the drainage catheter rather than into the right atrium, creating a phenomenon known as "Recirculation" that compromises the therapeutic efficacy of the VV ECMO. Generally as ECMO flow increases, the recirculation rate also increases, especially when a severely injured lung requires greater ECMO perfusion assistance. When recirculation occurs, the efficacy of VV ECMO is not only compromised, but also causes the blood to stay in the ECMO circuit for an extended period of time, causing more complications due to damage to the blood cells, which is not clinically desirable. For example, as the blood cells are recirculated in the ECMO circuit for a longer period of time, more blood cells are lysed, particularly in the narrow fiber passages of the Oxygenator (Oxygenator), causing bleeding or thromboembolic complications, resulting in the need to use higher doses of heparin anticoagulant.

Several solutions have been proposed to reduce the recirculation rate of VV ECMO, with practical implementation emphasis on improving catheter designs and related intubation methods. In combination with different types of catheter designs and intubation methods, there are four clinical intubation types of VV ECMO: 1) cannulation at two sites using a single-chamber catheter, 2) cannulation at a single site using a dual-chamber catheter, 3) cannulation at two sites using a dual-chamber catheter, 4) cannulation at three sites using a single-chamber catheter. In recent years, the single site intubation of double-lumen catheters has been achieved by commercially available Avalon catheters, and has gained increasing popularity in the european and american areas because of the reduced recirculation rate available with such catheters, as well as the ability to provide the patient with greater mobility to help the lungs recover more quickly.

All of the above cannula types use passive rather than active control components to reduce recirculation rates. Notably, the right ventricle can only receive perfusion with oxygenated blood when the heart is relaxed and the tricuspid valve is open. When the heart contracts and the tricuspid valve closes, the perfused oxygenated blood cannot enter the right ventricle no matter how the tip of the perfusion catheter is placed near the entrance to the tricuspid valve, which is the fundamental reason limiting the upper performance limit of all passive catheters. In the inventor's laboratory, a specially designed pulmonary circulation bionic physiological test platform has been developed, which can measure the recirculation rate of the VV ECMO. It was found that the recirculation rate of the conventional single chamber tube in the dual site cannula type was as high as 40-50% for the ECMO flow rate of 3.5 liters per minute, whereas the recirculation rate of the single site cannula type using the Avalon dual chamber tube was about 20-25%. Thus, there is still considerable room in the design to further improve the patient's ability to achieve better pulmonary VV ECMO therapy.

Patients with the device ECMO are usually sedated and bedridden in Intensive Care Units (ICU), and while the single site intubation version using a dual chamber catheter has the advantage that the patient can be ambulatory and recovery time is faster, it is difficult to achieve in practical clinical applications. In fact, the manpower of the care givers and staff in the intensive care unit in the vast majority of intensive care units around the world does not allow ECMO patients to get out of bed and walk around in corridors around the intensive care unit routinely and safely.

Generally, the diameter of the ECMO catheter is limited because the catheter with an excessively large diameter is difficult to insert into the blood vessel, and the catheter may be manipulated in the blood vessel to cause damage to the blood vessel and complications of the vessel lumen becoming narrow after the catheter is removed. The double-chamber catheter with the perfusion channel and the drainage channel existing simultaneously has the advantages that the channel caliber of the double-chamber catheter is smaller than that of the single-chamber catheter in nature, higher flow resistance and wall shear stress can exist in the double-chamber catheter inevitably, and therefore when blood flows out of the narrower drainage channel of the double-chamber catheter and then flows into the narrower perfusion channel, more blood cells can be damaged. In fact, ECMO flow is limited in double lumen catheters due to high flow resistance, which is undesirable for severe respiratory failure patients who urgently require large ECMO flow assistance.

Disclosure of Invention

The present invention takes the form of a specially designed dual-lumen catheter dual-site cannula, using electrocardiographic signals as a basis for a control system to improve recirculation to further reduce the recirculation rate, as will be described later. It should be noted in particular that the present invention differs from the previously described classification defining catheter lumens in that the dual lumen is defined as a tubular whole consisting of an air flow channel and a blood flow channel, wherein the cross-section of the blood flow channel is much larger than the cross-section of the air flow channel. In fact, the dual lumen catheter of the present invention has a blood flow impedance comparable to that of the single lumen catheter described above, thus allowing for the dual advantages of higher blood flow assist and less flow resistance in terms of hemodynamics. The use of a larger blood flow channel in the catheter greatly reduces the shear stress of the tubular flow, resulting in less damage to the blood cells, and clinical management advantages requiring less heparin and anticoagulation.

By adjusting the flow rate distribution for drainage and perfusion in accordance with the switching of the tricuspid valve, the recirculation rate of the VV ECMO can be minimized to a degree that is theoretically not achievable with the prior art. The present inventors believe that it would be desirable to further reduce the recirculation rate of current dual-chamber catheters in a single part-cannula version, while at the same time expanding the auxiliary range of ECMO flow with less damage to the blood cells. Given the time and blood flow characteristics associated with tricuspid valve motion, VV ECMO-assisted efficacy can be further improved by actuation of actively controlled actuators mounted on the catheter, allowing the afflicted lung to rest more fully and achieve faster recovery, greatly reducing the time the patient spends ECMO and stays in the intensive care unit, which will actually benefit the patient. While rehabilitation treatments to help accelerate lung recovery in patients may be performed after the patient has left the ECMO assist and moved out of the intensive care unit.

The present invention relates to an innovatively designed blood flow regulation system that can enhance venous-venous extracorporeal membrane oxygenation (VV ECMO) efficiency. The ECMO system comprises a drainage catheter, a perfusion catheter, a blood pump, an oxygenator and a pneumatic driver controlled according to electrocardiosignals. A catheter assembly for draining hypooxygenated blood from a vena cava to an ECMO system comprising: a Drainage catheter (Draainage Cannula), a Compliant Reservoir (Compliant Reservoir), a Drainage end obturator (Occluder), and a First Balloon (First Balloon). An infusion catheter assembly for infusing hyperoxygenated blood of ECMO into the vena cava or right atrium comprising: an Infusion catheter (Infusion Cannula), a cis-contained blood reservoir, an Infusion tip obturator and a Second Balloon (Second Balloon). These active components: balloon, obturator and passive components: the blood storage device can be used in the control system design, and uses the electrocardiosignal as the trigger reference of the system control logic to form the catheter component with the flow regulating component. Intermittent control of the occluder to control venous return and ECMO-driven drainage and perfusion in response to the opening and closing of the tricuspid valve allows for maximum perfusion of highly oxygenated blood into the right ventricle and subsequent re-flow into the pulmonary circulation. The use of this electro-cardio signal regulated VV ECMO can significantly reduce the recirculation of highly oxygenated blood back into the ECMO circuit, reducing the oxygenation load on the patient's lungs. Furthermore, reducing blood recirculation also reduces the residence time of blood in the ECMO circuit, helping to reduce the risk of blood cell damage such as hemolysis, thrombosis, and stroke.

The drainage catheter or perfusion catheter of the invention comprises an inflatable balloon which can be coated on a part of the outer surface of the catheter, or the balloon catheter and the drainage catheter or perfusion catheter are mutually combined to meet the designed functional requirement. The balloon material must be durable and biocompatible and made of a deformable or malleable elastomeric material. When the balloon is deflated, the balloon contracts to a low profile to reduce flow impedance. When the balloon is inflated, the balloon expands against or in close proximity to the vessel wall, thereby occluding the blood flow path. This intravascular catheter and balloon assembly is placed within a large venous vessel to account for drainage or perfusion of blood. The time interval and the backflow amount of the blocked blood returning to the right atrium from the superior vena cava or the inferior vena cava can be regulated by controlling the inflation and the deflation of the balloon on the catheter.

The catheter of the present invention may further include an adjustable occluder attached to the catheter, the occluder being located outside the patient's body. An occluder is a mechanism for compressing the pipe cross-sectional area of a pipe flow to reduce the flow, in other words, it slows down the flow of the internal pipe flow by increasing the resistance of the flow. Alternatively, the use of an internal balloon or flexible membrane to provide internal flow impedance may also be considered a broad type of occluder. Different blocking degrees, time points and time intervals are achieved by squeezing the stopper, so that the blood flow channel in the catheter can be regulated and controlled to have full-open, partially-open or closed states in the whole time sequence. Therefore, the time interval and the flow rate of the venous return blood sucked into the ECMO inflow end and the time interval and the flow rate of the high-oxygen blood flowing out of the ECMO outflow end can be regulated.

The function of the compliance reservoir is similar to the capacitance on the circuit, which is used to store or return blood and is in communication with the flow path of the ECMO in order to provide a stable and continuous operation of the ECMO blood pump when the balloon or stopper in the circuit is actuated. The passive positive displacement reservoir may be made of a resilient material and functions similarly to the positive displacement resilience of a human blood vessel. An active positive-Displacement reservoir, such as a positive Displacement Pump (Displacement Pump), can also be constructed in design, with the change in volume of the positive-Displacement reservoir being controlled by an external drive system. The compliant blood reservoir may be in series or parallel with the flow channel. Passive positive displacement reservoirs offer the advantage of a simple and streamlined flow path design, however, in some cases, the ability to actively control the volume of fluid entering or exiting the positive displacement reservoir may be more conducive to regulating flow in the ECMO circuit.

The balloon and the obturator use electrocardio signals as reference signals for controlling and triggering so as to activate the balloon and the obturator to actuate. The inflation and deflation of the balloon and the opening and closing of the occluder may be manipulated separately or in combination, as long as the points in time at which the tricuspid valve opens and closes are correctly matched in manipulation time. Such a maneuver is intended to store a maximum amount of hyperoxygenated blood in the right atrium before the tricuspid valve opens (ready for subsequent filling into the right ventricle during diastole), while allowing a large amount of venous return of depleted oxygen into the ECMO circuit during systole when the tricuspid valve closes. Furthermore, the compliance reservoir acts in conjunction with the stopper in order to compensate for the blockage of the flow in the ECMO circuit when the stopper is closed, and in the next phase when the stopper is open, the compliance reservoir acts like a booster to re-accelerate the blood stored and pressurized in the reservoir back into the ECMO circuit. The invention uses the VV ECMO active flow control system taking the electrocardio signal as the control reference, and can greatly reduce the recirculation rate in the traditional ECMO loop on the premise of not reducing the ECMO flow.

Drawings

Brief description of the drawingsthe present invention may be more particularly described by way of embodiments illustrated in the accompanying drawings. These drawings depict only typical embodiments of the invention and are not therefore to be considered to limit its scope of use. The presently contemplated embodiments and best mode of the invention will now be described using the accompanying drawings, in which:

fig. 1 is a schematic diagram depicting a VV ECMO circuit and pulmonary circulation. The control action characteristics of each of the six flow regulators when the diastolic tricuspid valve is open are presented.

Fig. 2 is a schematic diagram depicting a VV ECMO circuit and pulmonary circulation. The control action characteristics of each of the six flow regulators when the tricuspid valve is closed during systole are presented.

FIG. 3A is a control flow block diagram of the present invention.

Fig. 3B depicts the point in time (braking or not) associated with each flow regulator activation.

Fig. 4A and 4B are side views of a drainage catheter assembly according to embodiment 1 of the present invention.

Fig. 5A and 5B are longitudinal sectional views of a drainage catheter assembly according to embodiment 1 of the present invention.

Fig. 5C is a cross-sectional view of a drainage catheter assembly according to example 1.

Fig. 6 is a longitudinal cross-sectional view of a drainage catheter balloon according to example 1 of the present invention.

Fig. 7 is a schematic diagram depicting the placement of the drainage catheter of example 1 at the junction of the inferior vena cava and right atrium.

Fig. 8A and 8B are side views of a drainage catheter assembly according to embodiment 2 of the present invention.

Fig. 9A and 9B are longitudinal sectional views of a drainage catheter assembly according to embodiment 2 of the present invention.

Fig. 10 is a longitudinal cross-sectional view of a drainage catheter balloon according to example 2 of the present invention.

Fig. 11 is a longitudinal sectional view of a drainage Y-joint of a drainage catheter according to example 1 of the present invention.

Fig. 12A is a detailed illustration of the drainage Y-fitting of the drainage catheter according to example 2 of the present invention.

Fig. 12B is an exploded view of the drainage Y-joint of the drainage catheter according to embodiment 2 of the invention.

Fig. 13 is a schematic view depicting placement of the drainage catheter of example 2 at the junction of the inferior vena cava and right atrium.

Fig. 14A and 14B are side views of an infusion catheter assembly according to example 3 of the present invention.

Fig. 15A and 15B are cross-sectional views of an infusion catheter assembly according to example 3 of the present invention.

Fig. 16 and 17 are sectional views of an irrigation duct blocker according to embodiment 3 of the present invention.

Reference numerals

21: a perfusion catheter set; 23: a drainage catheter set; 30: a drainage catheter set; 40: a drainage catheter set; 50: a perfusion catheter set; 101: the superior vena cava; 102: the right atrium; 103: the tricuspid valve; 104: the inferior vena cava; 105: a right ventricle; 109: the pulmonary artery; 201: an oxygenator; 202: a blood pump; 203: a perfusion end blood reservoir; 205: a perfusion end occluder; 206: a perfusion catheter; 207: a perfusion end balloon; 208: a drainage end balloon; 209: a drainage end balloon; 210: a drainage end stopper; 211: an ECMO drainage catheter; 212: a drainage end blood reservoir; 301: a drainage catheter; 302: strengthened wall of the drainage catheter; 303: a drainage hole; 304: an inflow ramp; 305: sealing the end of the conduit; 310: an air conduit; 311: a balloon; 312: a balloon body; 313: a side hole; 314: a radiation opaque indicator; 315: a radiation opaque indicator; 316: a sealed conduit end; 317: a tapered extension; 401: a drainage catheter; 402: an ECMO tube; 403: a drainage hole; 404: strengthened wall of the drainage catheter; 411: an inner tube; 412: an outer tube; 414: an air conduit; 415: a balloon; 416: a catheter tip; 417: a balloon body; 418: an adhesive; 421: a radiation opaque indicator; 422: a radiation opaque indicator; 423: the top end is provided with a hole; 424: an inner tube cavity; 430: a Y-shaped joint; 431: a Y-shaped connector body; 432: a plug; 433: a Y slit cone; 434: locking the cover; 501: a perfusion catheter; 503: a side hole; 504: a tip opening; 511: an ECMO tube; 520: an occluder module; 521: an adapter; 522: a blood reservoir; 523: an occluder chamber; 524: a gas line; 525: an occluder; 526: an adapter; 527: a gas chamber.

Detailed Description

The focus of the control method is to regulate venous return and ECMO catheter flow based on tricuspid valve movement in order to reduce the drawbacks of VV ECMO recirculation. Fig. 1 and 2 show the position of each control assembly, and the mode of operation of each control assembly as the heart contracts and relaxes in order to reduce recirculation rates, respectively. Fig. 1 and 2 are schematic diagrams of a VV ECMO circuit and pulmonary circulation depicted in accordance with an embodiment of the present invention. Extracorporeal life support system 20 is comprised of oxygenator 201, blood pump 202, perfusion catheter assembly 21, and drainage catheter assembly 22. The oxygenator 201 and the blood pump 202 are disposed outside the patient's body. In addition, the infusion catheter assembly 21 is placed in a position opposite to the drainage catheter assembly 22. In one embodiment of the invention, the catheter assembly 22 may include a drainage end balloon 208, or may be equipped with a drainage end obturator 210 or a drainage end positive displacement reservoir 212, or both. In other embodiments of the present invention, perfusion tube assembly 21 may include perfusion end balloon 207, or may be equipped with perfusion end occluder 205, perfusion end compliant reservoir 203, or both.

In both figures, a drainage catheter 209 is placed in the inferior vena cava 104, and a drainage end balloon 208 is mounted on the drainage catheter 209. The end-stop 210 and the forward-volume reservoir 212 are disposed outside the patient's body and are connected to the ECMO drainage catheter 211. Similarly, perfusion catheter 206, perfusion end balloon 207, are also placed in the superior vena cava in a similar manner, with perfusion end occluder 205 and compliant reservoir 203 disposed outside the patient's body. It should be noted that in a surgical setting, the perfusion catheter 206 and the drainage catheter 209 may interchange the position of the cannula, as opposed to the cannula approach disclosed in fig. 1 and 2. In practice, the catheter assemblies 21, 22 may likewise be actively controlled using the control methods and hardware systems provided herein.

The control action with respect to the above flow regulating system will be explained below:

in diastole:

1. during diastole, the tricuspid valve 103, which is located between the right atrium 102 and the right ventricle 105, is open. Before the tricuspid valve 103 opens, the right atrium 102 should be filled with oxygenated blood as much as possible in preparation for entering the right ventricle 105. When the tricuspid valve 103 is opened, the oxygenated blood that has been stored in the right atrium 102 can flow in large quantities into the right ventricle 105 and fill it up. With this arrangement, the right ventricle 105 can be perfused with a maximum amount of oxygenated blood and, upon subsequent systole, eject the oxygenated blood into the pulmonary artery 109 and lungs to complete the pulmonary cycle.

2. During the late systole before tricuspid valve 103 opens and the next diastole when tricuspid valve 103 opens, balloon 207 and balloon 208 inflate to stop venous return from the superior vena cava and inferior vena cava 104, respectively, thereby preventing hypoxemia from entering right atrium 102, while arresting perfusion catheter 206 to perfuse oxygenated blood into the space of right atrium 102.

3. The perfusion occluder 205 of the infusion catheter assembly 21 is opened to allow oxygenated blood from the outflow end of the ECMO to enter the right atrium 102. Because of the time required for blood flow and mixing, right atrium 102 may be "lavaged" with oxygenated blood a short time earlier before tricuspid valve 103 opens. During this brief irrigation, both balloons 207 and 208 are inflated and both occluders 205, 210 are open. Thus, the blood stored in the right atrium 102 and the oxygenated blood previously stored in the perfusion end reservoir 203 during systole are mixed and forcibly discharged, so that oxygenated blood can be filled in large quantities into the right atrium 102 and is ready to enter the right ventricle 105.

4. The occluder 210 on the drainage catheter 209 is closed, preventing oxygenated blood in the right atrium 102 from being drawn into the inflow path of the ECMO. The occluder 210 at the drain end of the ECMO begins to close after the right atrium 102 has completed the "lavage" procedure and remains closed for most of the diastole, thus further reducing recirculation of oxygenated blood back into the ECMO circuit.

5. When the drain-side occluder 210 is closed, the drain-side reservoir 212, which has been passively filled with hypooxygenated or mixed blood during the last systole, supplies the stored blood to the ECMO circuit to maintain a steady, continuous operation of the ECMO blood pump.

The systolic phase:

1. during systole, tricuspid valve 103, which is located between right atrium 102 and right ventricle 105, is closed. During this time, the venous return should be maximally drawn into the ECMO drainage circuit and pushed through the oxygenator via the blood pump to produce oxygenated blood. Since venous return is impeded at the end-diastole, the Preload (i.e., pressure) of the inferior vena cava is increased, which accelerates the flow of the blood pump, thereby enhancing the pumping of the return blood from the inferior vena cava and helping to oxygenate the blood flow into the right atrium 102 during the initiation of the next diastole.

2. During systole, balloons 208, 207 of both catheter assemblies 21, 22 are deflated, thus creating a low pressure suction force that assists in the return of venous return blood from the superior vena cava and superior vena cava 104 and filling right atrium 105.

3. Occluder 205 of infusion catheter assembly 21 is closed to prevent oxygenated blood of the ECMO from entering right atrium 102. During this period of blocked ECMO perfusion, the oxygenated blood of the ECMO will be diverted to the perfusion end reservoir 203. As the volume of blood in the reservoir increases, the pressure in the reservoir 203 will rise to establish a pressure gradient with respect to the perfusion conduit, which will help to drain the stored blood in the reservoir 203 when the occluder 205 is opened in the next diastole.

4. The occluder 210 of the catheter assembly 22 is opened to receive venous return blood collected in the right atrium 102. With the help of the operation of the blood pump 202, blood drawn into the drainage catheter 209 will be pushed through the oxygenator 201 to produce oxygenated blood. At the same time, the reservoir 212 of the drainage catheter assembly 22 can be re-expanded and filled with additional hypoxic blood during this systole, and then drained during the next diastole when the stopper 210 at the drainage end is closed to maintain a steady flow of ECMO.

5. To maintain continuous operation of blood pump 202, oxygenated blood delivered by the ECMO will be pushed into the blood reservoir 203 in the infusion catheter assembly 21 for storage and gradually increase in pressure when the perfusion end occluder 205 is closed during systole. The high pressure blood stored in the perfusion end reservoir 203 will be expelled in a pressurized manner during the next diastole when the perfusion end occluder 205 is open.

The present invention includes six flow regulators distributed on the drainage catheter assembly 22 and the infusion catheter assembly 21, and a VV ECMO control system using ecg signals as a control reference, which is designed to reduce recirculation rate while maintaining a steady and continuous operation of the blood pump. For example, the flow regulator may include two balloons 207, 208, two occluders 205, 210 and two reservoirs 203, 212. Balloons 207, 208 are used to regulate the volume of venous return blood in the body, and occluders 210, 205 are used to prevent blood flow in the ECMO catheter from flowing through the drainage and perfusion ends, respectively. The blood reservoirs 212, 203 are placed before the blood pump 202 and after the oxygenator 201, respectively. The manner of control of the reservoirs 212, 203 may be active or passive, depending on the flow setting requirements to maintain continuous flow of the ECMO blood pump. The balloons 207, 208 are placed in the superior or inferior vena cava 104 and are therefore in contact with blood, and are designed with a configuration suitable for Hemodynamics (Hemodynamics) to avoid regions of stagnant blood flow (hemostatis). The occluders 205, 210 may be mounted inside or outside the conduits 206, 209, with occluder designs that are generally preferred that are extracorporeal and do not come into contact with blood. The present invention needs to develop a control logic design of an open-loop controller using an electrocardiographic signal as a control reference signal. Theoretically, current active control flow regulation systems are single input, multiple output controllers, with the control objective being to reduce the recirculation rate of the VV ECMO system. In practical design implementations, the six actuators (flow regulators) described above may all be selected, or some may be selected, or combined in different ways. The braking for each flow regulator with respect to those points in time on the cardiac signal has to be set adaptively. In general, all control parameters for a selected flow regulator must be optimized simultaneously to achieve the design goal of minimizing recirculation rates.

FIG. 3A is a control flow block diagram of the present invention. The heart rhythm (usually the waveform of the cardiac signal) can be continuously captured by the data capture system and amplified by an algorithm to detect the time point (i.e., the R-wave) when the heart begins to contract. Fig. 3B schematically depicts the triggering time points (braking or not) of each flow regulator braking. The steep rise and fall of the square wave over the time sequence shown in fig. 3B is representative of the braking and closing of the regulator, respectively. The point in time of braking or closing for each flow regulator is triggered timed relative to the R-wave. The magnitude of the time delay with respect to the R-wave is a predetermined control input parameter. There may be up to 12 control variables in the active control system, but depending on the selection of the combination of balloon, occluder and blood reservoir on the drainage and infusion catheter assembly of the ECMO system, it is possible to determine whether the control variables corresponding to the actuation and closure of the flow regulators are fully or only partially used. During design, the method can use a bionic cycle test bench experiment or an animal experiment to measure the recycle, and finds out the optimal control time point for reducing the recycle rate as a control input parameter through repeated experiments, thereby realizing the method in the VV ECMO invention.

In one embodiment of the present invention, the extracorporeal flow regulator system includes a pneumatic pump, a sensing system that can receive a signal indicative of heart rate, and a controller that can generate control commands based on a set control logic and the sensed heart rate signal. The control logic is optimized to allow the heart to perfuse a maximum amount of oxygenated blood into the right ventricle during diastole and to pump a maximum amount of venous return deoxygenated blood into the ECMO circuit during systole.

Example 1 balloon-fitted drainage catheter:

fig. 4A and 4B are side views of a drainage catheter assembly according to embodiment 1 of the present invention. Fig. 4A is a 1:1 scale depiction of the drainage catheter assembly, and fig. 4B is an enlarged view of fig. 4A. FIG. 4A example 1, depicting the balloon and side port of the device on the drainage catheter assembly. Fig. 5A and 5B are longitudinal sectional views of a drainage catheter assembly according to embodiment 1 of the present invention. FIG. 5C is a cross-sectional view of a drainage catheter assembly according to example 1, showing a lumen assigned to a smaller control air passage and a lumen assigned to a larger blood flow passage. Fig. 6 is a longitudinal cross-sectional view of the balloon of the drainage catheter of example 1 of the present invention showing the attachment of balloon, air holes, side blood drainage holes and radiopaque visualization markers. Like components appearing in different views are labeled similarly throughout the description.

The catheter assembly 30 typically includes two fluid channels, one capable of delivering or withdrawing blood, and another connected to the drainage end balloon 311 to drive the drainage end balloon 311 to inflate or deflate, such as drainage catheter 301 and drainage end air catheter 310. The drainage catheter 301 forms a first lumen and the drainage end air catheter 310 forms a second lumen, e.g., the drainage air catheter 310 can be disposed within the drainage catheter 301. In at least one embodiment, both the drainage cannula 301 and the drainage end air tube 310 of the drainage catheter assembly 30 have a portion of the sidewalls that merge into a common sidewall and the lumens of the two are separated by a septum. The lower (or proximal) end of the drainage catheter 301 can be conveniently connected to the ECMO tube using, for example, a barbed quick connector. The upper end (or distal end) of the other side of the drainage cannula 301 terminates in a sealed catheter end 316. Drainage catheter 301 mounts a drainage tip balloon 311 on the sidewall of conical extension 317 near sealed catheter end 316. Gas communication between balloon 312 and its designated extracorporeal controller is achieved through the drainage end air conduit 310 and further through side holes 313 drilled in the conical extension 317. The drain air conduit 310 is spaced from the drain assembly 30 at a location remote from the sealed conduit end 316, for example, the drain conduit 301 and the drain air conduit 310 are disposed at one end of the drain assembly 30 having the sealed conduit end 316. The drainage end balloon 311 and the side holes 303 are arranged and distributed at the tip region of the drainage catheter assembly 30. For a drainage end air tube 310, the side port 313 is located inside the drainage end balloon 311 and near the sealing tube end 316. The separation junction of the drainage end air conduit 310 will be separated from the location where the drainage catheter assembly 30 exits the skin incision in the exterior of the patient's body by an appropriate distance. In this embodiment, the merged transition is reinforced and protected by the bifurcated structure of the drainage catheter assembly 30 having a greater wall thickness.

A plurality of openings or drainage apertures 303 are disposed along the length of the drainage catheter 301. Drainage holes 303 are distributed on the section below balloon 311. The sets of drainage apertures 303 are preferably arranged in a staggered manner to maximize the amount of venous return blood that can be drawn. The wall 302 of the conduit between the array of drainage holes and the separate transition zone is reinforced with a polymer or metal wire. Because the catheter end 316 is sealed, the drainage holes 303 in the side wall of the drainage sleeve 301 should have a smooth internal inflow bevel 304 to seal the catheter tip 305 to avoid local areas of blood flow blockage around the drainage holes 303.

As shown in FIG. 6, the drainage end balloon 311 is mounted on the exterior of a conical extension 317 that is connected to the sealing catheter end 316 of the drainage catheter assembly 30. Indicators 314, 315 on either side of the drainage end balloon 311 are attached to the drainage catheter 301, are made of a material that is opaque to radiation, and are integrated or embedded into the drainage catheter 301. The balloon may be manufactured using a polymeric material such as, but not limited to, silicone or Polyurethane. The balloon volume 312 is about 3-15 ml, depending on the size of the vessel to be inserted and the vessel occlusion ratio to be achieved when the balloon 311 is inflated to prevent venous return. Pneumatic communication of balloon 311 with a designated controller is accomplished via air tube 310, which terminates at one end in a flow regulator and at the other end in a tapered extension 317, and causes the reduced pressure or compressed air to move back and forth to deflate or inflate balloon 311 in accordance with the control commands.

Blood drains from a drainage catheter 301 placed in the superior or inferior vena cava. Fig. 7 is a schematic view showing the relative insertion position of the current drainage cannula at the junction of the inferior vena cava 104 and the right atrium 102.

This example is a conversion application of the working principle shown in fig. 1 and 2. It should be noted that in fig. 1 and 2, blood enters the ECMO circuit only through the distal end of the balloon 311, and the blood reservoir 212 needs to be actuated in conjunction with the stopper 210 to regulate flow within the ECMO circuit. The catheter in this embodiment has a sealed catheter end 316 and an array of drainage holes 303 distributed about balloon 311, and reservoirs 212, 203 or occluders 210, 205 may be omitted or both omitted to simplify the hardware set-up and control logic design.

When the drainage end balloon 311 is inflated to block the flow of oxygenated or mixed blood from the right atrium 102, the sealed catheter end 316 helps prevent the oxygenated or mixed blood from being drawn into the ECMO circuit, thus reducing undesirable recirculation. Although the drainage end balloon 311 is inflated, venous return hypoxemic blood at diastole may be continuously drawn in from the plurality of drainage holes 303. Therefore, the time when the blood is pumped into the vein and flows back does not exist, and the operation of a blood storage device is avoided to maintain the continuous operation of the ECMO blood pump without interruption. In fact, controlling the catheter to occlude flow and regulate venous return in this embodiment is controlled by a mechanism that is fused to a balloon catheter with a sealed end. When the drainage end balloon 311 is inflated, venous return blood from the superior or inferior vena cava is drained out through the drainage holes 303 depending on where the drainage catheter 209 is placed. When the drainage end balloon 311 is deflated, the venous return of both the superior and inferior vena cava can be withdrawn into the drainage catheter 209. The drainage end balloon 311 may also act as a flow stop to prevent recirculation of flow in the right atrium. The local high pressure caused by flow deceleration and occlusion from the occlusion of the drainage end balloon 311 accompanying inflation of the drainage end balloon 311 diverts the flow of infused oxygenated blood to the tricuspid valve 103. if the balloon inflation time point is assumed to be properly controlled in coordination with relaxation of the right ventricular muscle and opening of the tricuspid valve, this change in flow direction may cause the right ventricle to be infused with the maximum amount of oxygenated blood, collectively creating a push-pull driving force for the right ventricle to receive an accelerated flow of perfusion from the right atrium.

A common commercially available single-chamber perfusion catheter (without moving parts or fitted flow regulators) can be used to work with the current drainage catheter embodiment, thus constituting a low recirculation rate VV ECMO loop. In practice this assembly is the simplest actively controlled VV ECMO device.

Example 2: assembling a drainage catheter of a non-tight coupling balloon:

fig. 8A and 8B are side views of a drainage catheter assembly according to example 2 of the present invention to show the relationship between a balloon catheter and an inserted single-lumen drainage catheter. Fig. 8A is a 1:1 scale depiction of a drainage catheter assembly, and fig. 8B is an enlarged view of fig. 8A. The drainage catheter assembly 40 includes a drainage catheter 401, a drainage end air catheter 414, and a drainage end Y-fitting 430. FIGS. 9A and 9B are longitudinal sectional views of a drainage catheter assembly according to example 2 of the present invention, showing the internal relationship when the drainage tip air catheter is inserted inside the drainage catheter assembly. Fig. 9A is a 1:1 scale depiction of the drainage catheter assembly, and fig. 9B is an enlarged view of fig. 9A. The drainage catheter 401 is integrated with the air catheter 414 and Y-connector 430. in fig. 9A and 9B, an active control flow occluder is shown that provides regulated venous return blood by utilizing a balloon 415 and air catheter 414. Fig. 10 is a longitudinal cross-sectional view of the balloon of the drainage catheter of example 2 showing the balloon, the airflow port, the blood drainage side port, and the radiopaque marker. Fig. 11 is a longitudinal cross-sectional view of the Y-connector of the drainage catheter of example 2, showing the design of the Y-connector to provide access for air catheterization and control of areas of blood flow stagnation. The configuration of the Y-site 430 detailed in FIGS. 11, 12A and 12B includes an adapter that provides for insertion of an air tube into the drainage catheter without blood leakage and air ingress as the air tube is fed into the drainage catheter.

The drainage catheter assembly 40 is a thin-walled tube made of a biocompatible polymeric material such as, but not limited to, polyurethane or silicone. In this embodiment, the catheter tip 416 is open and a plurality of drainage holes 403 are drilled along the wall of the drainage catheter 401 immediately adjacent to the catheter tip opening 416. These drainage holes 403 are designed to draw a maximum amount of venous return regardless of whether the balloon 415 is inflated or deflated. To achieve less trauma during surgical insertion, the catheter is therefore thin-walled and the added thread-embedding reinforcement unit 404 allows for smooth and kink-free insertion of the catheter. The lower half of the drainage catheter assembly 40 is gradually enlarged to reduce flow resistance and provide a structural transition to interface with the Y-connector 430.

Fig. 9A and 9B depict insertion of an air catheter into the drainage catheter assembly 40. The air tube 414 is generally straight prior to insertion of the drainage tube, but the flexible nature of the air tube 414 allows the air tube 414 to bend along the path of insertion. The air conduit 414 may generally include an inner tube 411 (to sense pressure) and an outer tube 412 (to deliver air), with the inner tube 411 disposed longitudinally within the outer tube 412. Surrounding the upper end of the air conduit 414 is a balloon 415 made of a polymer such as polyurethane or silicone. Balloon 415 may be controlled to expand or contract by an actuator system external to the body. Fig. 8A, 8B, 9A, 9B and 10 show a fully inflated balloon 415 that conforms to the shape of a dip-formed mandrel or a blow-formed mold. The balloon 415 is seamlessly bonded or connected to the air tube 414. Figure 10 shows a preferred balloon engagement, with the distal end of the balloon tube seamlessly bonded to the inner tube 411 and the proximal end of the balloon tube seamlessly bonded to the outer tube 412. The inner tube 411 typically has an outer diameter dimension of about 1 mm. Saline may be injected to fill inner tube cavity 424 to form a water pressure sensing channel and extend to tip opening 423 to facilitate measurement of vena cava blood pressure during ECMO operation. Gas communication between balloon 417 and the extracorporeal controller is achieved via the luminal space between inner tube 411 and outer tube 412. To assist in the placement of the balloon 415 in place during insertion, radiopaque markers are provided at the proximal end 422 and distal end 421 of the balloon 415. The catheter tip 416 is lined on the distal portion of the inner tube 411 to form a smooth contour to protect the vessel from injury during catheter advancement.

As shown in fig. 12A and 12B, the Y-connector 430 generally includes a Y-shaped body 431, a Y-slit hemostatic cone 433, a plug 432, and a locking cap 434. The two sides of the main arm of the Y-connector 430 are respectively butted together with the drainage catheter 401 and the ECMO tube 402 to form a drainage channel for extracting venous return blood of the inferior vena cava or the superior vena cava. A plug 432 is provided in a side arm of the Y-fitting 430 for use with a Y-slit cone 433 to form a sealing mechanism when the air conduit 414 is pushed and installed. The plug 432 and Y-slit cone 433 are typically made of an elastically deformable polymer such as silicone or rubber. One side of the plug 432 is mounted flush against the inner wall of the drainage catheter. It is generally desirable to create a smooth, continuous flow interface at the surface of the plug where the air tube 414 enters the drainage tube 401 and contacts the blood, to minimize the possibility of blood clots forming at surface discontinuities around the drainage tube and air tube interface. At the other end of the plug 432 is received a Y-slit cone as a haemostatic valve.

To install the air tube 414, the air tube 414 is first inserted through the Y-slit cone 433 and then the air tube 414 is pushed through the channel wall of the plug 432. The outer wall of the air tube 414 and the passage of the plug 432 should be designed with appropriate clearance so that the air tube remains smooth and does not leak during the forward pushing of the air tube. As shown in fig. 11, the locking cap 434 is coupled to the Y-shaped connector body 431 by a screw thread, and the number of turns of the screw thread is used to control the pressing force of the locking cap 434 on the Y-slit cone 433 to provide different sealing effects. During insertion of the air tube 414, the locking cap 434 is released to release the engagement between the air tube 414 and the balloon 415 with the stopper, and then locked to compress the Y-slit cone 433 to prevent blood backflow from between the drainage tube and the air tube interface edge for hemostasis purposes. When the ECMO blood pump is in operation, a negative pressure gradient is created along the catheter to draw blood, so the blood pressure around the Y-shaped fitting 430 is typically below atmospheric pressure, and the Y-slit cone 433 hemostasis valve must provide a tight seal to prevent outside air from being drawn into the blood stream. Failure of a tight seal can produce an Air Embolism (Air Embolism) that can be life threatening to the patient.

In the practical application of this example 2, the intubation process is completed in two steps. The first step is to implant the drainage catheter 401 using a tool set of needle, guidewire, and introducer. This procedure is the same procedure that a typical surgeon would clinically perform a single lumen catheter inserted into the ECMO system from either the superior or inferior vena cava sites. The second step is to introduce an air conduit 414. The balloon 415 on the air tube 414 is deflated to a smaller profile ready for insertion through the entrance of the Y-slit cone 433 hemostasis valve. The locking cap 434 is first released to receive the air tube 414, then advanced along the drainage catheter 401 after the air tube 414 has passed through the plug 432, and finally locked after the balloon 415 is properly positioned outside the catheter tip opening 416 to the desired position. An imaging system may be used to perform precise guidance to accomplish the placement of steps 1 and 2. Fig. 13 shows the insertion and placement of the present example 2 at the junction of the inferior vena cava and right atrium.

Example 3: perfusion catheter fitted with occluder:

the infusion catheter assembly 50 of this example 3 is shown in fig. 14A and 14B. Fig. 14A is a 1:1 scale view of an infusion catheter assembly, and fig. 14B is an enlarged view of fig. 14A. Fig. 15A and 15B are cross-sectional views of the infusion catheter assembly of example 3 showing details of the relationship between the occluder, blood reservoir and the combination of the infusion catheter and ECMO tube. Fig. 15A is a 1:1 scale depiction of an infusion catheter assembly, and fig. 15B is an enlarged view of fig. 15A. Perfusion cannula assembly 50 includes a perfusion conduit 501, an occluder module 520, a gas line 524, and an ECMO tube 511, wherein the occluder module 520 is serially connected between the perfusion conduit 501 and the ECMO tube 511, respectively. The occluder module 520 includes an occluder 525 disposed in an occluder chamber 523 and a blood reservoir 522. In one embodiment of the invention, occluder 525 is connected to perfusion conduit 501 and reservoir 522 is connected to ECMO tube 511. The perfusion cannula 501 is a common single-chamber catheter, like the catheter disclosed in example 2. The occluders (perfusion occluders) 525, 205, 210 and (perfusion) reservoirs 522, 202, 212 are arranged in series to reduce flow resistance, wherein regulation of perfusion flow may be achieved by compressing or expanding the cross-sectional size of the occluders (perfusion occluders) 525, 205, 210, or by passive reservoirs 522, 203, 212 acting with the occluders (perfusion occluders) 525, 205, 210 to control volume and maintain continuous operation of the blood pump in the life support system. The tip opening 504 and side hole 503 on the perfusion catheter are used to provide perfusion of blood. For example, the tip opening 504 is disposed at one end of the perfusion catheter 501, and the side hole 503 is disposed on the sidewall of the perfusion catheter 501. The occluder 525 currently designed to stop blood flow in perfusion catheter 501 is a flexible catheter with distributed wall thickness. When the catheter is compressed with air, perfusion occluder 525 in occluder chamber 523 will be squeezed to reduce the cross-sectional area and prevent or slow the flow of perfused blood, while perfusion reservoir 522 will expand in response to receiving the blocked flow, allowing the flow in the ECMO circuit to continue to operate. Indeed, the manner in which the present embodiment operates in conjunction with the stopper and reservoir functions has been shown and described with respect to FIGS. 1 and 2. The reservoir volume is passively reacted with the active occlusion flow control provided by the extracorporeal flow regulation system.

Fig. 16 and 17 show the detailed structure of the stopper module. Figure 16 depicts the occluder and blood reservoir operation in diastole with the occluder in a fully open state and the blood reservoir held in an unexpanded stretched state. Figure 17 depicts occluder and reservoir operation during systole with the occluder in a fully closed state with the reservoir elastically expanded to receive flow from the ECMO circuit. The current occluder subsystem generally includes a barbed adapter 521, an occluder module 525, a gas chamber 527, and a gas line 524 connected to the gas chamber 527 at the barbed adapter 526. The occluder module 525 is controlled via pneumatic communication with a flow regulation system outside the body. The ECMO tube 511 is connected to the occluder module 520 via a barbed adapter 521. The stoppers 525 of the stopper module 520 are sealingly coupled to both ends of the gas chamber 527. The gas chamber structure is rigid or semi-rigid relative to the flexible conduit, so the cross-sectional area of the stopper 525 can be controlled as the pressure of the gas chamber is adjusted. The infusion cannula 501 is quickly connected to the distal end 523 of the occluder using a barbed adapter.

The extracorporeal life support system of the above-described embodiments of the present invention may include only one balloon 207, 208, 311, 415, one occluder (module) 205, 210, 525 or one reservoir 203, 212, 522. Balloons 207, 208, 311, 415, either with occluders (modules) 205, 210, 525 or blood reservoirs 203, 212, 522 or both, may be actuated according to the patient's heart rhythm, so that most oxygenated blood enters the right ventricle during diastole and most venous return hypoxic blood is drawn into the life support circuits during systole.

The present invention may be embodied in other specific forms without departing from the basic control principles disclosed and explained herein. The embodiments described herein are to be considered in all respects only as illustrative and not restrictive. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.