The present invention relates to an appliance for the support of biomedical devices during extracorporeal circulation, in particular for the support of an oxygenator and of the relevant pumping assembly.
As is well known, in the event of certain surgical operations, during which the functions of the patient's heart are temporarily suspended, extracorporeal blood circuits are created using the so-called “heart-lung” machines.
The heart-lung machines comprise a series of devices including a filtration device (also called “venous reserve”) adapted to filter the blood coming from the patient, a heat exchanger adapted to regulate the temperature of the blood coming out of the filtration device, and an oxygenator adapted to provide the correct supply of oxygen to the blood intended to be returned to the patient. In particular, the blood coming from the patient is sent to the oxygenator by means of a relevant pumping assembly, which generally comprises a centrifugal pump of the dragging or magnetic levitation type, i.e. provided with a rotor element adapted to send the incoming blood to the oxygenator as a result of the rotation thereof and with a stator element adapted to drive the rotor element in rotation.
During extracorporeal circulation, a number of parameters have to be monitored and controlled, including the number of revolutions of the rotor element and the flow rate of blood sent to the oxygenator.
Appropriately, during the extracorporeal circulation applied to a patient, a supporting appliance is generally used having a load-bearing body provided with first supporting means of the oxygenator, second supporting means of the relevant pumping assembly and provided with a command and control unit connectable at least to the pumping assembly for the command and control of the aforementioned parameters.
This appliance is now particularly used also in non-hospital environments since extracorporeal circulation is also applied in emergency situations, e.g. road rescue, where there is the need to adequately support the various devices in a dynamic context and with a flexible manner.
The appliances of known type for the support of biomedical devices, in particular for the support of the oxygenator and the relevant pumping assembly, do have some drawbacks.
In particular, they do not allow the oxygenator and the relevant pumping assembly to be easily and practically supported and moved according to the specific needs.
Another drawback of these appliances of known type is that they are not able to adequately support the oxygenator and the relevant pumping assembly during extracorporeal circulation activity both in non-hospital emergency situations and in hospital situations.
The main aim of the present invention is to devise an appliance which allows supporting the oxygenator and the relevant pumping assembly in a practical and functional manner during the application of extracorporeal circulation to a patient.
Within this aim, one object of the present invention is to enable medical staff to set up the oxygenator and the relevant pumping assembly in the optimal position with respect to the patient, so as to facilitate the connection to the other medical devices and the fluid dynamics of the blood.
Another object is to simplify the movement of the oxygenator and of the relevant pumping assembly in the event of their position needing to be changed with respect to the load-bearing body.
Yet another object of the present invention is to devise an appliance that is flexible in use and that allows effectively supporting the oxygenator and the relevant pumping assembly, or even just one of them so as to allow the separate movement thereof, even if the patient has to be moved, without interrupting the extracorporeal circulation applied to them.
Another object of the present invention is to devise an appliance for the support of biomedical devices during the extracorporeal circulation which allows overcoming the aforementioned drawbacks of the prior art in the ambit of a simple, rational, easy, effective to use and low cost solution.
The objects set out above are achieved by the present appliance for the support of biomedical devices during extracorporeal circulation according to claim 1.
Other characteristics and advantages of the present invention will be more evident from the description of a preferred, but not exclusive, embodiment of an appliance for the support of biomedical devices during extracorporeal circulation, illustrated as an indication, but not limited to, in the attached tables of drawings in which:
With particular reference to these illustrations, reference numeral 1 globally indicates an appliance for the support of biomedical devices during extracorporeal circulation, in particular for the support of an oxygenator and of the relevant pumping assembly.
The appliance 1 comprises at least one load-bearing body 2, preferably of the transportable type and positionable on a reference surface, at least one command and control unit 3 operationally connectable to at least one biomedical device to control the functionalities thereof, and at least one holding element 4 associated with the load-bearing body 2 and provided with first supporting means 5 of a first biomedical device O and with second supporting means 6 of a second biomedical device P.
More particularly, the first biomedical device O is of the type of an oxygenator and the second biomedical device P corresponds to the relevant pumping assembly, e.g. of the type of a centrifugal pump. In the embodiment shown in the figures, the centrifugal pump P, although not part of the present invention, is of the dragging or magnetic levitation type and comprises at least one hollow body inside which is housed a rotor element (impeller) adapted to transfer the venous blood coming from a patient to the oxygenator O and at least one motor adapted to control the rotor element at least in rotation.
The command and control unit 3 is connectable to the centrifugal pump P, comprises at least one microprocessor which is programmed to control the relevant motor and is suitably provided with a plurality of drives 3a that can be operated by one operator as well as with at least one display 3b for displaying the parameters that can be controlled by means of the drives 3a. More in detail, the drives 3a allow controlling at least the number of revolutions of the rotor element and the flow rate delivered.
Appropriately, the load-bearing body 2 has a front portion 2a, intended to be facing the patient, a rear portion 2b, opposite the front portion 2a and accessible by an operator to actuate the drives 3a, and two lateral portions 2c interposed between the front portion 2a and the rear portion 2b.
According to the invention, the first supporting means 5 and the second supporting means 6 are locked to each other and the holding element 4 comprises removable hooking means 7 to the load-bearing body 2.
The holding element 4 is advantageously made in a single body piece.
In the preferred embodiment shown in the figures, the holding element 4 has a substantially slab-like conformation, i.e. the thickness thereof is significantly lower than the other dimensions.
Preferably, the holding element 4 has at least a first holding wall 4a with which the first supporting means 5 are associated and at least a second holding wall 4b with which the second supporting means 6 are associated, where the first and second holding walls 4a and 4b are arranged transversely to each other.
More in detail, in use, i.e. during the use of the appliance 1 when extracorporeal circulation is applied to a patient, the first holding wall 4a is substantially arranged (i.e. less the machining tolerances and/or the positioning on a non-planar reference surface) vertically and the second holding wall 4b is substantially arranged (i.e. less the machining tolerances and/or the positioning on a non-planar reference surface) horizontally.
The first supporting means 5 are advantageously arranged at a greater height with respect to the second supporting means 6.
The result, therefore, is that, in use, the oxygenator O is arranged on top of the relevant pumping assembly P, thus facilitating, from a fluid-dynamic point of view, the transfer of blood from the pumping assembly P to the oxygenator O.
Appropriately, the holding element 4 comprises at least one intermediate wall 4c adjacent to the first holding wall 4a, arranged substantially transverse thereto and adapted to be arranged, in use, below the oxygenator O.
More in detail, the intermediate wall 4c is arranged substantially (i.e. less the machining tolerances) parallel to the second holding wall 4b and at a greater height with respect thereto.
In the embodiment shown in the figures, the first holding wall 4a is arranged substantially perpendicular to the second holding wall 4b and to the intermediate wall 4c.
The second holding wall 4b and the intermediate wall 4c define in practice therefore two substantially parallel and staggered planes.
Preferably, the first supporting means 5 comprise at least one housing seat 8 associable with the oxygenator O and configured to keep the oxygenator itself in suspension on the first holding wall 4a. More particularly, the housing seat 8 has a curvilinear extension in such a way as to at least partly wind the body of the oxygenator O. The housing seat 8 is configured so as to receive the oxygenator O by interlocking and/or defines at least one abutment surface on which the oxygenator itself rests.
Advantageously, the first supporting means 5 are associated with the holding element 4 in a removable manner. More specifically, the first supporting means 5 comprise removable fixing means 5a, e.g. of the type of one or more interlocking elements, to the holding element 4.
Appropriately, the first supporting means 5 are of the disposable type and are intended to be applied to the oxygenator O prior to the sterilization thereof.
The second supporting means 6 are instead arranged at the second holding wall 4b and are configured to keep the centrifugal pump P in position on the second holding wall itself.
More in detail, the second supporting means 6 can be of the type of a threaded member (as in the embodiment shown in the figures) which passes through the second holding wall 4b and which is adapted to engage with the containment body of the motor of the centrifugal pump P, or they can be of the interlocking type, slide type or other type known to the expert in the field.
Advantageously, the hooking means 7 are movable from at least one engagement configuration to a release configuration with the load-bearing body 2. In the preferred embodiment shown in the figures, the hooking means 7 comprise two hooking elements 7a movable in the direction of mutual close/away movement. More particularly, in the engagement configuration, these hooking elements 7a are close to each other and are movable in the direction of mutual away movement, counteracting elastic means (not visible in detail in the figures), in order to reach the release configuration.
Appropriately, the hooking means 7 comprise at least one activation element 7b which can be activated by an operator to bring the hooking elements 7a from the engagement configuration to the release configuration.
In turn, the appliance 1 comprises at least one gripping element 9 associated with the load-bearing body 2 and with which the hooking means 7 are adapted to engage in a removable manner.
In the preferred embodiment shown in the figures, the gripping element 9 is of the type of an element with an elongated shape and protruding from the load-bearing body 2 so as to define a profile engageable by the hooking elements 7a in the engagement configuration. Alternatively, the gripping element 9 can be recessed with respect to the load-bearing body 2.
Conveniently, the gripping element 9 is of the joined type, i.e. its conformation and its dimensions are made according to codified and standardized regulations.
In particular, the gripping element 9 corresponds to the profile also found on stretchers used in hospitals.
Advantageously, the appliance 1 comprises at least two gripping elements 9 which are separate from each other, so as to allow positioning the holding element 4 on the load-bearing body 2 in at least two different positions that can be selected by the operator according to the specific needs.
More in detail, at least one of the gripping elements 9 is associated with the front portion 2a of the load-bearing body 2, while another gripping element 9 is associated with at least one of the lateral portions 2c of the load-bearing body itself. This way the holding element 4 is positionable on the load-bearing body 2, at the operator's will, in at least two positions which are substantially orthogonal to each other.
Preferably, the appliance 1 comprises first protection means 10 of the first biomedical device, i.e. the oxygenator O. More particularly, the first protection means 10 are associated with the load-bearing body 2 and are shaped so as to surround the oxygenator O. In the preferred embodiment shown in the figures, the first protection means 10 are e.g. of the type of a curved bar. Appropriately, the first protection means 10 are movable from a work position, wherein they are arranged to surround the oxygenator O, and a home position, wherein they are displaced with respect to the work position so as to facilitate the application or removal of the holding element 4 to/from the load-bearing body 2. In the embodiment shown in the figures, the first protection means 10 are hinged to the load-bearing body 2 at its front portion 2a and rotate upwards to displace from the work position to the home position. More specifically, the first protection means 10 are associated with the load-bearing body 2 in a removable manner so as to reduce the overall dimensions of the appliance 1.
Advantageously, the appliance 1 also comprises second protection means 11 of the second biomedical device, i.e. of the pumping assembly P. More particularly, the second protection means 11 are associated with the load-bearing body 2 and are shaped so as to surround the pumping assembly P. Appropriately, the second protection means 11 are movable between a work position, wherein they are arranged to surround the pumping assembly P, and a home position, wherein they are displaced from the work position in such a way as to reduce the overall dimensions of the appliance 1. In the embodiment shown in the figures, the second protection means 11 are hinged to the load-bearing body 2 at its front portion 2a and rotate upwards to move from the work position to the home position. In particular, the second protection means 11 are of the type of a curved bar shaped so as to resume, in the home position, the profile of the front portion 2a on which it rests.
The operation of the present invention is as follows.
Depending on the specific needs, i.e. on the position of the patient and of the other devices that make up the appliance used for extracorporeal circulation, the operator positions the holding element 4 at the front portion 2a or the lateral portion 2c of the load-bearing body 2.
In particular, the operator operates the activation element 7b to bring the hooking elements 7a to the release configuration and, after they have been positioned at the gripping element 9 of interest, releases the activation element itself so as to allow it to be engaged with the gripping element 9.
This way the holding element 4 is locked together with the load-bearing body 2.
The operator then positions the oxygenator O and the pumping assembly P on the holding element 4 by means of the first and second supporting means 5 and 6 respectively.
As mentioned above, the oxygenator O is preferably associated with the first supporting means 5 before the sterilization thereof. The first supporting means 5 are, therefore, of the disposable type.
More in detail, the oxygenator O is fitted inside the housing seat 8, while the centrifugal pump P is positioned at the second holding wall 4b and blocked with respect thereto by means of the threaded member 6.
After the various devices have been connected to each other and have been connected to the patient, it is possible to start the extracorporeal circulation by monitoring and possibly modifying some parameters of the centrifugal pump P, such as the number of revolutions and the flow rate delivered, by means of the command and control unit 3.
In case the patient is placed on a stretcher, whether in hospital or out of hospital, it is possible, always operating on the hooking means 7, to release the holding element 4 from the load-bearing body 2. In particular, the operator can operate again on the activation element 7b to bring the hooking elements 7a to the release configuration and thus remove the holding element 4 from the load-bearing body 2. The holding element 4 can then be applied to the stretcher's structure, always using the hooking means 7.
Appropriately, the holding element 4 is arranged at a lower height than the patient's one in order to optimize the fluid dynamics of blood circulation.
It has in practice been ascertained that the described invention achieves the intended objects and in particular it is emphasized that it allows optimally positioning the oxygenator and the relevant pumping assembly during the extracorporeal circulation applied to a patient.
In particular, the shape of the holding element makes it possible to move both the oxygenator and the centrifugal pump at the same time, keeping them in the same mutual position.
In addition, the hooking means make it possible both to vary the position of the holding element on the load-bearing body and to apply it to a hospital stretcher, thus making it flexible and practical to use.
Number | Date | Country | Kind |
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102019000001149 | Jan 2019 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/050477 | 1/22/2020 | WO | 00 |