INSULATED MEDICAL INSTRUMENT ROBOT WITH LONG-SIDED MEDICAL INSTRUMENT AND ASSOCIATED ACCESSORIES

专利摘要:
The invention relates to the field of elongated flexible medical instrument insertion robots (1, 2), elongated flexible medical instrument training modules (1) (1, 2) included in these insertion robots, and accessories associated with these insertion robots. An elongated flexible medical instrument insertion robot (1, 2) in a patient (9) includes one or more elongated flexible medical instrument training modules (1) (1, 2) in this patient (9) . An elongate flexible medical instrument drive module (1) (1, 2) transmits to this elongated flexible medical instrument (1, 2) a translational movement and / or a rotational movement which can be sluggish. The main object of the invention is to reduce this softness effect by acting at various locations along the transmission chain between the distal end of the elongated flexible medical instrument (1, 2), the last portion to undergo rotational movement originally printed by the user at a man-machine control interface of the drive module (3). The progression of the elongated flexible medical instrument (1, 2) is thus rendered more efficient for the progress of this progression, more secure for the patient (9) and more ergonomic for the practitioner who is the user of the patient. elongated flexible medical instrument (1, 2).
公开号:FR3048891A1
申请号:FR1657678
申请日:2016-08-10
公开日:2017-09-22
发明作者:Philippe Bencteux；Sebastien Deboeuf；Fabien Destrebecq；Julien Maurel；Marc Boulange；Bruno Fournier
申请人:Robocath；
IPC主号:

专利说明:

INSULATED MEDICAL INSTRUMENT ROBOT WITH LONG-SIDED MEDICAL INSTRUMENT AND ASSOCIATED ACCESSORIES
FIELD OF THE INVENTION The invention relates to the field of elongated flexible medical instrument insertion robots, guiding or other elongated flexible medical instrument of the elongated flexible medical instrument training modules included in these robots. insertion of elongated flexible medical instrument, and accessories associated with these elongated flexible medical instrument insertion robots. These accessories include, in particular, elongated non-motorized linear rail and elongated flexible medical instrument flexible elongated medical instrument drive systems, elongated rail flexible medical instrument drive systems. motorized linear and elongated flexible medical instrument drive module, sterile barriers between consumable and non-consumable parts in elongated flexible medical instrument insertion robots, flexible medical instrument guide tracks elongated in robots elongated flexible medical instrument insertion instrument, articulated arms carrying the drive module into elongated flexible medical instrument insertion robots, arterial introducer fittings into elongated flexible medical instrument insertion robots , guide rollers in flexible medical instrument insertion robots allon ge, the elongated flexible medical instrument insertion robot remote control stations incorporating shields.
BACKGROUND OF THE INVENTION
An elongated flexible medical instrument insertion robot in a patient includes an elongated flexible medical instrument insertion driver in this patient. The elongated flexible medical instrument insertion driving module transmits to the elongated flexible medical instrument a translational movement and / or a rotational movement that can optionally be combined with one another.
Transmission of this translational movement and / or rotational movement should be controlled to allow smooth and efficient progression of the elongated flexible medical instrument into the patient. This transmission of movement being effected over a certain distance, the control of this transmission is neither immediate nor automatic.
Indeed, especially when a rotational movement about its axis is printed to a flexible medical instrument elongated at an intermediate portion thereof, this rotational movement is not transmitted immediately and regularly to its distal end located on the side of the patient.
On the contrary, because of the friction, difficult passages and curvatures suffered by this flexible medical instrument elongated during its progression, it is with delay and by jerks that stored energy is continuously released suddenly, causing a movement rotation by saccade from its distal end. In response to a rotation at constant speed that is printed by the robot at the proximal end, located on the insertion robot side, of the elongated flexible medical instrument, there is an irregular rotational speed of the distal end of the the elongated flexible medical instrument.
This slack effect is both troublesome and disruptive to the user of the elongated flexible medical instrument training module. This softness effect will be further amplified by the use of an elongated flexible medical instrument retractor.
This softness effect will be aggravated by all the eccentricities of the elongated flexible medical instrument, whether they are geometric or that they concern variations in the density of material. Indeed, such eccentricities of the elongated flexible medical instrument will increase the contrast between the easier rotation zones and the harder rotation zones, accentuating the jerky nature of the transmission of the rotational movement between the human machine interface of control and the distal end of the elongated flexible medical instrument. In practice, this causes "jumps" of rotation which make the control of the angle of rotation more delicate.
This softness effect is also aggravated by the tortuosity of the course followed by the flexible medical instrument elongated during its progression.
The main object of the invention is to reduce this slack effect, by acting at various locations along the transmission chain between the distal end of the elongated flexible medical instrument, the last portion of the flexible medical instrument elongated at to undergo the rotational movement originally printed by the user at a human machine control interface of the drive module of the elongated flexible medical instrument.
This advantageously allows not to aggravate the effect of soft, or at least very little aggravate, even compared to a manual manipulation directly benefiting all the fingering of the practitioner.
The progression of the elongated flexible medical instrument is thus rendered more efficient for the progress of this progression of the elongated flexible medical instrument, which is more secure for the patient and more ergonomic for the practitioner who is the user of the elongated soft medical instrument.
For this, various tools and accessories included in the elongated flexible medical instrument insertion robot are proposed to the practitioner to help him precisely to control this progression in the patient of the elongated flexible medical instrument.
SUMMARY OF THE INVENTION
The object of the present invention is to provide tools and accessories included in the elongated flexible medical instrument insertion robot at least partially overcoming the aforementioned drawbacks.
More particularly, the invention aims to provide tools and accessories included in the elongated flexible medical instrument insertion robot proposed to the practitioner to help him precisely to control this progression in the patient of the elongated flexible medical instrument.
A first object of the invention concerns, in the elongated flexible medical instrument insertion robot, an interaction between the drive module and the rail on which it slides, based on a non-motorized linear rail and on a drive module. motorized. To improve the management of the soft effect, this interaction eliminates the reel usually used to wind the elongated flexible medical instrument and amplifying the soft effect. However, the absence of winder causes a significant stroke of the drive module on the linear rail with the problem of sterility management throughout this length of race. The management of this sterility throughout this length of race is a prejudice to the skilled person dissuading to remove the reel. To this end this first object of the invention proposes an elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising: an arm, a non-motorized linear rail and carried by the arm, a flexible elongated flexible motorized instrument driving module, sliding along the linear rail.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, the motorized elongated flexible medical instrument drive module comprises two parts separable from one another: a reusable and non-contacting motor with the linear rail, a disposable carriage sliding on the linear rail, this carriage being preferably for single use .
Thus, only the portion of the drive module in contact with the elongated flexible medical instrument itself in contact with the patient, which is the simplest and least expensive part, will have to be discarded. On the other hand, the part of the training module, which is not in direct contact with the elongated flexible medical instrument or indirectly with the patient, which is the most complex and the most expensive part, will be able to be preserved.
Preferably, the sliding of the disposable carriage on the linear rail performs the translational movement of the elongated flexible medical instrument.
Thus, the simple movement of the drive module on the linear rail automatically achieves without additional element one of the four desired movements that are the translation and / or rotation of the elongated flexible medical instrument.
Preferably, the disposable carriage comprises a contact surface with the linear rail, this contact surface being E-shaped so that the disposable carriage rests on three of the four faces of the linear rail.
Thus, the drive module is very well supported, guided and supported by the linear rail, if it must move on the linear rail, and well worn, guided and supported by the linear rail, even if it must move on the side or below the linear rail.
Preferably, the linear rail is disposable, and preferably the linear rail is disposable.
Thus, the problem of sterility is managed with maximum efficiency, for a reasonable cost, since the disposable rail here remains a fairly simple and inexpensive element because the motorization has been totally excluded.
Preferably, the drive system also comprises a sterile consumable barrier passing between the reusable motor and the disposable carriage secured to each other.
Thus, the sterility is better guaranteed, even in the sensitive area that constitutes the consumable and non-consumable portion of the training unit boundary.
Preferably, this sterile barrier comprises a plate which is pierced so as to pass the couplings between disposable carriage and reusable motor and which is surrounded by a film attached to the edges of the plate.
Thus, the risk of damaging the sterile barrier in the zone of high mechanical stress that is the consumable and non-consumable part boundary of the drive module, is reduced.
Preferably, this sterile barrier includes the disposable trolley which is surrounded by a film attached to the edges of the disposable trolley.
Thus, the assembly constituted by the consumable part of the drive module on the one hand and by the sterile barrier itself on the other hand forms a more compacted, more compact entity, which can be more easily removed after the diagnosis of the patient and throwing of a block with a reduced risk of contamination of other elements that can be either the non-consumable part of the drive module or the non-consumable part of the drive module and the sterility barrier to be put in place for the diagnosis of the next patient.
Preferably, the drive system also includes another consumable sterile barrier encompassing the entire arm, but neither the linear rail nor the elongated flexible medical instrument drive module.
Thus, the consumable portion of the drive module is completely isolated, in a sterile manner, not only the non-consumable part of the drive module, but also the rest of the drive system also not consumable.
Preferably, the stroke of the motorized module along the linear rail is between 60cm and 120cm.
Thus, a large race of the drive module is maintained, despite the absence of the retractor.
Preferably, the linear rail comprises at least one groove guiding the elongated flexible medical instrument.
Thus, the elongated flexible medical instrument is carried and driven by the drive module while remaining guided in its majority by the linear rail. The drive module and the linear rail cooperate together to guide the elongated flexible medical instrument over its entire length.
Preferably, the groove is closed by a cover which opens to the passage of the motorized module and which closes after the passage of the motorized module.
Thus, the elongated flexible medical instrument is still better protected, even outside the training zone by the drive module.
Preferably, the arm comprises: a column movable on the one hand in vertical translation and on the other hand in horizontal translation, two V-shaped bars, the tip of the V preferably comprising a ball joint connection connecting it to the top of the mobile column, the free ends of the V being preferably fixedly connected to the linear rail.
Thus, the structure of the arm makes it possible to bring the training module closer to the arterial introducer placed in the patient, which then makes it possible, with the only linear stroke of the linear rail, to carry out the entire path of the elongated flexible medical instrument at inside the patient.
Preferably, the drive system also comprises locking elements for locking the assembly constituted by the arm, by the linear rail and by the motorized module, so that this assembly can be moved in one piece by report to the operating table.
Thus, the adjustment time of the positions of the different elements of the arm can be gained during an intervention.
Preferably, the motorized drive module contains a catheter drive module and a drive module of the guide in translation and in rotation.
Thus, the movement of the guide can be decoupled from that of the catheter, allowing the guide to play its full role by sending it in front of the catheter, pass through and pass through all the difficult areas, allowing the catheter to progress smoothly, regularly and effective.
Preferably, the motorized elongated flexible medical instrument drive module is driven by a wireless link and / or has as its main energy source, preferably exclusive, one or more electric batteries.
Thus, its maneuverability and autonomy are improved.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
A second object of the invention concerns in the elongated flexible medical instrument insertion robot, an interaction between the drive module and the rail on which it slides, based on a motorized linear rail and a non-motorized drive module. . To improve the management of the soft effect, this interaction eliminates the reel usually used to wind the elongated flexible medical instrument and amplifying the soft effect. However, the absence of winder causes a significant stroke of the drive module on the linear rail with the problem of sterility management throughout this length of race. The management of this sterility throughout this length of race is a prejudice to the skilled person dissuading to remove the reel. The consumable part of the entire drive system is less important than in the case of the first subject of the invention, since there is only a part of the drive module and the sterility barrier, to the exclusion of the linear rail. This motorization of the linear rail is however a little more complex than the only motorization of the drive module in the case of the first subject of the invention. To this end, this second object of the invention proposes an elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising: an arm, a motorized linear rail and carried by the arm, an elongated flexible medical instrument drive module, sliding along the linear rail under the effect of the sole motorization of the linear rail.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, the elongated flexible medical instrument drive module comprises two parts separable from one another: a reusable carriage sliding on the linear rail, a disposable support without contact with the linear rail, this support being preferably for single use, resulting in the elongated flexible medical instrument.
Thus, only the part of the drive module in contact with elongated flexible medical instrument itself in contact with the patient, which is the simplest and least expensive part, will have to be discarded. On the other hand, the part of the training module, which is not in direct contact with the elongated flexible medical instrument or indirectly with the patient, which is the most complex and the most expensive part, will be able to be preserved.
Preferably, the drive system also comprises a sterile consumable barrier passing between the reusable carriage and the disposable support secured to each other.
Thus, the sterility is better guaranteed, even in the sensitive area that constitutes the consumable and non-consumable portion of the training unit boundary.
Preferably, the sterile consumable barrier, passing between the reusable carriage and the disposable support joined together, which also encompasses the entire arm.
Thus, the consumable part of the drive module is completely isolated, in a sterile manner, not only from the non-consumable part of the drive module, but also from the rest of the drive system which is also non-consumable, and this with the use of a single sterile barrier and not two sterile barriers as in the first subject of the invention.
Preferably, the motorized drive module contains a catheter drive module and a drive module of the guide in translation and in rotation.
Thus, the movement of the guide can be decoupled from that of the catheter, allowing the guide to play its full role by sending it in front of the catheter, pass through and pass through all the difficult areas, allowing the catheter to progress smoothly, regularly and effective.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
A third object of the invention concerns, in the elongated flexible medical instrument insertion robot, the protection of the sterile nature of an interaction between the drive module and the rail on which it slides, or of an interaction between module drive and robotic arm at the end of which it evolves. To improve the management of the softness effect, this interaction eliminates the reel usually used to wrap the elongated soft medical instrument and amplifying the softness effect. However, the removal of the reel causes a significant stroke of the drive module on the linear rail or robotic arm end with the problem of sterility management over this entire race length.
The management of this sterility throughout this length of race is a prejudice to the skilled person dissuading to remove the reel. This third subject of the invention facilitates and improves the management of this sterility. To this end, this third subject of the invention proposes a method for producing a sterile barrier between the consumable and non-consumable parts of an elongated flexible medical instrument drive system of a robot insertion robot. elongated flexible medical instrument, comprising a step of installing a consumable sterile skirt separating a linear rail from at least a portion of an elongated flexible medical instrument drive module in this medical instrument drive system flexible lengthened. To this end, this third object of the invention also proposes a consumable sterile skirt adapted to separate a linear rail from at least a portion of an elongated flexible medical instrument training module in a training system. elongated flexible medical instrument of an elongated flexible medical instrument insertion robot, thereby achieving a sterile barrier between the consumable and non-consumable portions of this elongated flexible medical instrument drive system. To this end, this third object of the invention further proposes an elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising a sterile barrier between its consumable and non-consumable parts, comprising: a linear rail, an elongated flexible medical instrument drive module, a consumable sterile skirt separating the linear rail from at least a portion of the elongated flexible medical instrument drive module.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, the skirt is longitudinally wrinkled, on each side of the elongated flexible medical instrument drive module, so as to maintain the sterility barrier for the entire travel in translation of the elongated flexible medical instrument drive module. along the linear rail.
Thus, the crumpled parts, elongating and then narrowing in phase opposition from one another, allow to maintain just enough sterile cover on each side of the drive module, for all the positions of the drive module, all along the travel in translation. This way of providing the sterile protection by allowing the skirt to absorb and compensate the movements of the drive module is particularly simple and effective.
Preferably, the wrinkled skirt comprises lateral elastics for holding the wrinkled skirt around the linear rail.
Preferably, the skirt is longitudinally wrinkled, on each side of a central portion corresponding to a fixation at the level of the elongated flexible medical instrument training module, so as to be able to maintain the sterility barrier for the entire translational stroke. of the flexible medical instrument drive module elongated along the linear rail, the crimped skirt advantageously comprising lateral elastics for holding the wrinkled skirt around the linear rail.
Thus, the skirt is better held around the rail, reducing or eliminating the risk for the skirt to fall to one side or the other of the rail.
Preferably, the skirt is longitudinally split while having a cover on one side of the slot on the other side of the slot so as to maintain a sterility channel around the linear rail.
Thus, the sterility is well guaranteed, without significant risk of having dust sliding between the two parts of the skirt which overlap each other. However, this overlap of one part of the skirt by the other has a slight handling complexity and requires a certain rigidity of the material of the skirt so as not to fall spontaneously under its own weight.
Preferably, the slot opens under the effect of a shape before moving away from the elongated flexible medical instrument drive module and closes under the effect of a rear closure form of the drive module. of elongated flexible medical instrument.
Thus, on the one hand the passage of the drive module is ensured and secondly the sterility is maintained permanently over most of the race, only the portion of the race corresponding to the passage of the drive module being very temporarily or fleetingly open when passing the module.
Preferably, the skirt is longitudinally split while having slot sides that are joined so as to maintain a sterility channel around the linear rail.
Thus, the skirt simply closes, while ensuring sufficient sterility. However, the connection with the drive module is performed under the linear rail, which is a little more difficult to manage to avoid any risk of dust introduction in the wrong places.
Preferably, the slot opens under the effect of a shape before moving away from the elongated flexible medical instrument drive module and closes under the effect of a rear closure form of the drive module. of elongated flexible medical instrument.
Thus, it is the movement itself of the drive module which ensures the opening in front of him and the closing behind him of the skirt, without requiring the intervention or the use of other additional opening element and / or closing.
Preferably, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot also includes a pouch surrounding the elongated flexible medical instrument drive module.
Thus, sterility is provided by two distinct elements, one ensuring the sterility of the rail only, and the other ensuring the sterility of the drive module only.
Preferably, the elongated flexible medical instrument driving system of an elongated flexible medical instrument insertion robot also comprises a first winder / uncoiler secured to a first end of the flexible medical instrument drive module. elongated, a consumable sterile first skirt immobilized on one side with respect to a first end of the linear rail, and located on the other hand in the first winder / unwinder so as to be respectively wound or unwind in the direction of moving the flexible medical instrument drive module elongated along the linear rail, the first consumable sterile skirt being secured on one side to the first end of the linear rail, a second winder / uncoiler secured to a second end of the module; Elongated Flexible Medical Instrument Training, A Second Sterile Consumable Skirt immobilized on one side with respect to a second end of the linear rail, and located on the other side in the second winder / unwinder so as to be able to wind or unroll respectively while the first consumable sterile skirt unfolds or wraps, the second consumable sterile skirt being secured on one side to the second end of the linear rail.
Thus, the sterility is very well assured, because there is no hole in the sterility barrier, even of small size, even temporary or fugitive. However, the use of two reels makes this device ensuring relatively complex and expensive sterility.
Preferably, the consumable sterile skirt has a length that is at least two times the stroke of the flexible medical instrument drive module elongated along the linear rail.
Preferably, the consumable sterile skirt is smooth over its entire surface.
Thus, this type of skirt is very simple structure. The required flexibility is ensured by an excess of material which can however become important.
Preferably, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot also includes, an arterial introducer, a hood located on the side of the arterial introducer arranged to bring the sterile consumable skirt on the opposite side from that of a flexible medical instrument drive module elongated with respect to the slide plane of the linear rail.
The presence of the hood allows the excess material of the skirt not to interfere with the arterial introducer, when it is no longer used to cover the stroke of the drive module, that is to say say here when the drive module has arrived in the vicinity of the arterial introducer.
Preferably, the consumable sterile skirt is attached to the linear rail, and the elongated flexible medical instrument drive system includes another consumable sterile skirt that covers both the linear rail and the medical instrument drive module. flexible lengthened.
Thus, a good degree of sterility can be ensured thanks to this double level of sterile protection. However, this system ensuring sterility is relatively bulky and expensive, each skirt on the one hand taking up space and on the other hand to be removed and replaced at the end of each patient examination.
Preferably, the expendable sterile skirt is disposed around the linear rail so as to be rotated about the linear rail, about an axis perpendicular to the longitudinal axis of the linear rail, when the elongated flexible medical instrument drive module moves along the linear rail.
Thus, the skirt is of relatively simple structure. However, a precise dimensioning is required to allow a smooth sliding of the skirt when accompanying the movement of the drive module, otherwise there is a slight risk of snagging that must be avoided.
Preferably, the consumable sterile skirt is weighted to remain around the linear rail.
Thus, the skirt opening is held down by gravity, improving the maintenance of sterility.
Preferably, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot also includes flanges for guiding the rotation of the consumable sterile skirt around the linear rail.
Thus, the skirt opening is held down by guiding the guide flanges, thereby improving the maintenance of sterility.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
A fourth object of the invention concerns, in the elongated flexible medical instrument insertion robot, the protection of an interaction between the drive module and the rail on which it slides, or of an interaction between the drive module. and robotic arm at the end of which it evolves, in particular the protection of the flexible medical instrument elongated in the area between the drive module and the arterial introducer. To improve the management of the softness effect, this interaction eliminates the reel usually used to wrap the elongated soft medical instrument and amplifying the softness effect. However, the removal of the retractor causes a significant stroke of the drive module on the linear rail or robotic arm end with the problem of protecting the flexible medical instrument elongated on any area between the drive module and the arterial introducer. The protection of this area throughout this race length is a prejudice to the skilled person discouraging him to remove the reel. This fourth object of the invention facilitates and improves the protection of this area between the drive module and the arterial introducer. To this end, this fourth object of the invention proposes an elongated flexible medical instrument training system, characterized in that it comprises: an elongated flexible medical instrument, an elongated flexible medical instrument training module, whose displacement causes the elongated flexible medical instrument to move, preferably by pushing the elongated flexible medical instrument, an arterial introducer, a flexible medical instrument guide track elongated between the medical instrument drive module elongated flexible and arterial introducer.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, the guide track is structured to open and then preferentially to close in the passage of the elongated flexible medical instrument drive module.
Thus, the maintenance of the elongated flexible medical instrument is better ensured, because it is only during the passage of the drive module and at the level of this drive module that there is an opening of this guide track of the elongated flexible medical instrument; indeed, elsewhere and the rest of the time, the guideway remaining closed, the elongated flexible medical instrument is securely held in place without risk of leaving this guide track.
Preferably, the guide track is a split tube.
Thus, the maintenance of the elongated flexible medical instrument is ensured by means of a simple structure.
Preferably, the guide track is closed by a zipper or by a zip.
Thus, the maintenance of the elongated flexible medical instrument is ensured by a somewhat more efficient structure.
Preferably, the guide track is a profile that is flexible when open and is rigid when folded and closed.
Thus, the maintenance of the elongated flexible medical instrument is ensured by a robust and efficient structure. This embodiment presents a particularly good compromise between on the one hand the relative simplicity of the structure and on the other hand its high efficiency coupled with high reliability.
Preferably, the profile comprises: a bottom, two side rails respectively connected to the bottom and articulated with respect to this bottom, two closure elements, respectively located on the two side rails, able to cooperate together to close the profile, the closed cavity the profile being then delimited by the bottom, the two side rails and the two closure elements.
Thus, the maintenance of the elongated flexible medical instrument is ensured by a true rigid-walled channel that protects the elongated flexible medical instrument.
Preferably, the dimensions of the longitudinal members and the bottom, in a cross section of the profile, are determined so that, on the one hand the section is self-supporting when the closing elements are closed, on the other hand the section is not self-supporting, when the closing elements are open. The self-supporting character of the profile means in particular that this section retains a linear shape or at least only curves in a limited way when it is carried by its two ends.
Thus, the maintenance of the elongated flexible medical instrument is ensured by a structure that does not hang down too much when it is open and that the elongated flexible medical instrument is no longer inside. The size of this holding structure in place of the elongated flexible medical instrument is reduced.
Preferably, the closure elements mate by clipping into each other.
Thus, the maintenance of the elongated flexible medical instrument is ensured by a simple and effective structure, allowing both opening and closing fast, successively a large number of times without deterioration of the structure.
Preferably, the joints are material thickness weakenings.
Thus, the maintenance of the elongated flexible medical instrument remains assured by a structure which, in addition to being robust, is relatively flexible to allow opening and closing both fast and wide, without ceasing to maintain well. in place the elongated flexible medical instrument. In addition, this flexibility allows folding in several segments facilitating disposal.
Preferably, the material thickness losses are notches each with parallel bevelled edges.
Thus, once the profile again in the closed position, the walls of this profile are quite rigid, almost as in the absence of such weakening.
Preferably, each notch has a widened bottom with respect to the width between the bevelled edges.
Thus, despite the many openings and closures at these weakenings, there will be no premature wear that may eventually lead to premature rupture of the walls of this section at the bottom of these weakenings.
Preferably, the guide track is in the form of a cable-holder chain having a longitudinal opening which is of a width smaller than the diameter of the elongated flexible medical instrument and which is flexible but asymmetrical so as to leave the instrument Flexible medical elongated more easily enter than go out.
Thus, the guide track is particularly strong and protective of the elongated flexible medical instrument located therein, but the structure of this guide track is relatively complex.
Preferably, the guide track is in the form of a spiral wrapping around the elongated flexible medical instrument, which spiral is rotatable around the elongated flexible medical instrument.
Thus, the guide track has a relatively simple structure, but the guidance of the flexible medical instrument elongated by rotation of the spiral may be a little more delicate.
Preferably, the guide track comprises two parts which are fixed at one end to the elongated flexible medical instrument drive module, which are respectively fixed by the other end inside two winders, which form only a single band on the outside of these two reels in which they wind up respectively as the flexible elongated medical instrument drive module is slid towards the arterial introducer.
Thus, the guide track has the advantage of shrinking as the drive module advances, and therefore to be temporarily less cumbersome. However, this is obtained at the cost of a relatively large complexity of the structure of the guide track, due to the presence of the two reels.
Preferably, the guide track comprises two flexible crenellated rectangular portions when they are separated from one another constituting a rigid pipe of rectangular section when they are fitted one inside the other.
Thus, the guide track is relatively robust in the closed position and relatively flexible in the open position, which is interesting. However, here again, this guide track has a certain complexity and requires a reduced manufacturing tolerance to ensure proper interlocking of the slots into each other.
Preferably, the guide track is in the form of a bellows.
Thus, the guide track is robust and scalable length with the movement of the drive module. However, this guide track is on the one hand relatively bulky and on the other hand allows to ensure that a limited range of movement of the drive module.
Preferably, the guide track comprises: an open and rigid guiding channel in the hollow of which is located the elongated flexible medical instrument, a flexible cover which is fixed at one end to the elongated flexible medical instrument drive module, and which is fixed by the other end inside a reel in which it winds as the flexible elongated medical instrument drive module slides towards the arterial introducer.
Thus, the cover of the guide track has the advantage of shrinking as the progress of the drive module, and therefore to be temporarily less cumbersome. The guide channel remains fixed length. However, this is obtained at the expense of a relatively complex structure of the guide track, due to the presence of a winder.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
A fifth object of the invention concerns, in the elongated flexible medical instrument insertion robot, an interaction between the drive module and the robotic arm at the end of which this drive module evolves. To improve the management of the soft effect, this interaction eliminates the reel usually used to wind the elongated flexible medical instrument and amplifying the soft effect. The absence of retractor here causes a lower stroke than in the case of the use of a linear rail on which slides the drive module. However, if the problem of the management of sterility over the entire displacement of the drive module is facilitated, it is at the cost of an increase in the mechanical complexity of the support of the drive module; indeed, the robotic arm has a number of joints that could discourage the skilled person to remove the elongated flexible medical instrument retractor. To this end, this fifth object of the invention proposes an elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising: an articulated arm comprising at least three segments articulated with one another and robotic which is adapted to have a linear trajectory in space at its distal end described, an elongated flexible medical instrument drive module secured to this distal end.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, the orientation, in space, of the elongated flexible medical instrument drive module is kept constant during its movement along said linear path.
Thus, the movement control of the elongated flexible medical instrument drive module is easier and the movement of the elongated flexible medical instrument drive module is more fluid.
Preferably, this linear trajectory in space remains in a horizontal plane, that is to say in a plane parallel to the plane of the examination table. The linear trajectory can then either be perfectly horizontal or have a slight angle with the examination table.
Thus, the displacement of the drive module is more easily controllable and controllable.
Preferably, this arm comprises at least four segments articulated together, advantageously only four segments articulated between them.
Thus, more degrees of freedom are available to allow movement of the drive module as desired.
Preferably, the elongated flexible medical instrument drive system of an elongate flexible medical instrument insertion robot also comprises: an adjustment rail carrying the proximal end of this arm, a locking device of this end proximal of the arm on the adjustment rail during the linear displacement of this distal end.
Thus, the overall movement of the training module is split into two movements. First, a first movement of positioning of the training module to place this training module in the right place to begin its race, this good place of departure of race varying according to the morphology of the patient and according to the point d selected entry into the patient for the elongated flexible medical instrument. Then, a second movement movement of the drive module along its displacement path corresponding to the progression of the flexible medical instrument elongated in the patient. The adjusting rail is in charge of this first positioning movement of the drive module, while the robotic arm is in charge of this second movement of movement of the drive module. This split in two movements, movement of positioning of the drive module first, then movement of movement of the drive module afterwards, makes it possible to better manage and better optimize each of these two distinct movements. In addition, the motorization power required is reasonable.
Preferably, the adjustment rail rests on an examination table, advantageously fixed on this examination table.
Thus, any relative movements between the examination table and the ground do not need to be compensated because they do not affect the progression of the elongated flexible medical instrument in the patient.
Preferably, the proximal end of this arm rests on an examination table, articulated by a rotational connection relative to this examination table, preferably articulated only by this rotational connection with respect to this examination table.
Thus, the overall structure of the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot is simplified. However, the amplitude of the degrees of freedom of movement will be relatively small except to have long and robust segments of the robotic arm.
Preferably, the elongated flexible medical instrument driving system of an elongated flexible medical instrument insertion robot also comprises: an adjustment rail carrying a non-articulated stem which is secured to the proximal end of this arm , a locking device of this bracket on the adjusting rail during the linear displacement of this distal end.
Thus, the motorization required is quite low, especially because of the elevation obtained by the gallows. However, the number of elements and subassemblies is relatively large, significantly increasing the overall complexity of the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot.
Preferably, the adjustment rail rests on an examination table, advantageously fixed on this examination table.
Thus, any relative movements between the examination table and the ground do not need to be compensated because they do not affect the progression of the elongated flexible medical instrument in the patient.
Preferably, the elongated flexible medical instrument driving system of an elongated flexible medical instrument insertion robot also comprises: a non-articulated stem resting on the ground to which the proximal end of said arm is secured, a device for controlling the movement of an operating table during the linear displacement of this distal end.
Preferably, the gallows rests on the ground.
Thus, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot is made completely independent of the examination table. However, the relative movements between the examination table on the one hand and the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot on the other hand must be compensated.
Preferably, the stem is higher than the examination table associated with the elongated flexible medical instrument drive system.
Thus, the motorization required becomes weaker, since the effort required to counter the effect of gravity is less important.
Preferably, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot also comprises: an articulating adjustment arm carrying the proximal end of this robotic arm, a locking device this articulated control arm during the linear displacement of this distal end.
Thus, the required motorization becomes weaker for the displacement of the drive module along its stroke, due to the high number of degrees of freedom that includes the positioning device of the drive module before starting its travel stroke .
Preferably, the articulated arm of adjustment rests on an examination table, advantageously fixed on this examination table.
Thus, the possible relative movements between the examination table and the ground no longer need to be compensated because they no longer affect the progression of the flexible medical instrument elongated in the patient.
Preferably, the articulated control arm comprises at least three segments articulated together.
Thus, a great freedom of movement is given to the positioning device, which can therefore more easily bring the drive module closer to the desired position, close to the arterial introducer.
Preferably, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot also comprises: a column to which the proximal end of this robotic articulated arm is secured, and all segments Robotic articulated arm deploys only in a horizontal plane.
Thus, the required motorization is practically reduced to a minimum, since all the movement of the drive module along its stroke and its drive system is performed in a horizontal plane, without the need to fight against gravity. Although a height adjustment can be proposed, it is low energy consumption, unlike the movement of the drive module along its stroke, longer and more frequent. However, it is precisely this movement of the drive module along its stroke and the displacement of its drive system, which are maintained in the horizontal plane, thus allowing an optimized reduction of the associated motorization. This embodiment is particularly interesting insofar as it makes it possible to achieve most of the desired movements while minimizing the power of motorization required and limiting the volume swept.
Preferably, the column is non-articulated.
Thus, this column is simpler and more robust.
Preferably, the elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot also comprises: an adjustment rail on which the column rests, a locking device of this column on the rail during the linear movement of this distal end. The adjustment rail is advantageously horizontal.
Thus, more flexibility is provided, allowing more degrees of freedom in adjustment, while retaining this important advantage of a motorization or motorization very reduced (s) for the drive module and for its drive system.
Preferably, the adjustment rail rests on an examination table.
Thus, the possible relative movements between the examination table and the ground no longer need to be compensated because they no longer affect the progression of the flexible medical instrument elongated in the patient.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
A sixth object of the invention relates to a connection between arterial introducer and guide tube of the elongated flexible medical instrument of an elongated flexible medical instrument insertion robot. This connection has good performance in operation in order to keep the flexible medical instrument lying in the arterial introducer during the progression of the flexible medical instrument elongated in the patient, while ensuring the safety of the patient by avoiding the risk of tearing during an accidental movement or effort by the patient to remove the arterial introducer from the patient. This safety is ensured by a disconnection of the arterial introducer from the rest of the guide tube of the flexible medical instrument elongated during an accidental movement or effort of the patient, this disconnection being caused by this movement or this accidental effort . This connection should disturb only a minimum passage of elongated flexible medical instrument that passes through it, otherwise the effect of slackening. To this end, this sixth object of the invention proposes a connection between arterial introducer and guide tube of the elongated flexible medical instrument of an elongated flexible medical instrument insertion robot, comprising two parts interconnected by less a first attachment, now the arterial introducer in the extension of the guide tube to move the elongated flexible medical instrument from the guide tube to the arterial introducer by pushing the elongated flexible medical instrument, the tensile strength, along the axis of the elongated flexible medical instrument passing through the connector, the first fastener, before releasing the two parts of the connector, is less than the resistance of the arterial introducer introduced into the patient before he comes out.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, the connection between the arterial introducer and the elongated flexible medical instrument guide tube of an elongated flexible medical instrument insertion robot comprises four parts interconnected by at least one first fastener, holding the introducer arterial extension of the guide tube for passing the elongate flexible medical instrument from the guide tube to the arterial introducer by pushing the elongated flexible medical instrument, which first link connects two of the portions on one side of a plane transverse to the two other parts located on the other side of this transverse plane, comprises at least one second fastener, cooperating with the first fastener to immobilize, between them, the four parts of the coupling, the arterial introducer and the guide tube , this second fastener connecting two of the parts situated on one side of a longitudinal plane to the two other parts located in On the other side of this longitudinal plane, the tensile strength along the axis of the elongated flexible medical instrument passing through the connector of the first fastener prior to its release is less than this resistance of the second fastener. before his release.
Thus, on the one hand the various elements can be introduced into the fitting and mounted in easily, and this without these different elements need in turn to have particular characteristics allowing a rapid separation, while allowing a smooth passage of the flexible medical instrument elongated from one part to the other part of this connection, and secondly, during an accidental effort of the patient likely to injure the patient, a separation is carried out quickly and clearly between these two parts of the fitting respectively keeping each part of the elements with them.
Preferably, the second fastener cooperates with a flexible hinge which facilitates the opening and closing of the second fastener.
Preferably, the first attachment comprises at least one central clip, and preferably several longitudinal clips, the second clip comprises at least one lateral clip, and preferably several lateral clips.
Thus, fast and clean separation is facilitated.
Preferably, the second fastener secures the guide tube to the coupling via a sleeve surrounding the guide tube, which sleeve can be held in place in the connection by the second fastener at several positions along the axis. of this sleeve.
Thus, the connector can easily adapt to several sizes and / or several forms of arterial introducer, which result in different penetration lengths of the corresponding arterial introducers in the connection, while guiding practically continuously the elongated flexible medical instrument. between the guide tube and the arterial introducer.
Preferably, this sleeve has splines along its axis.
Thus, the virtually continuous guidance of the flexible medical instrument elongated between the guide tube and the arterial introducer can be provided in a simple manner, in fact with the aid of an additional element certainly but simple structure.
Preferably, these grooves are arranged periodically along the axis of the sleeve.
Preferably, the number of grooves is between 5 and 15, advantageously 10, the dimension of the hollow as the bump of each groove being between 0.5mm and 2mm, advantageously 1mm.
Thus, the substantially continuous guidance of the elongate flexible medical instrument between the guide tube and the arterial introducer can be ensured for a substantially continuous range of arterial introducer penetration values into the fitting.
Preferably, this sleeve is permanently fixed on the guide tube that surrounds it.
Thus, the assembly of the coupling is simplified and shortened, since a basic assembly operation has been removed instead of having to be done again at each new assembly of the fitting.
Preferably, the connector comprises a lateral opening allowing the introduction, in the connection, of another pipe coming from the arterial introducer.
Thus, this new constraint does not interfere with the kinematics of rapid and rapid disconnection of the connection, nor complicate the completion of the various parts of the connector allowing rapid disconnection and precipitated connection in case of accidental effort and inappropriate patient.
Preferably, the connector system comprises: a connector according to any one of the preceding claims, an arterial introducer, an elongate flexible medical instrument guide tube of an elongated flexible medical instrument insertion robot.
Preferably, the connection system comprises a catheter and a coaxial guide.
Thus, this connection system continues to ensure rapid disconnection almost instantaneous, while allowing the fluid passage not only a catheter but also a guide.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
A seventh object of the invention relates to a set of rotating rollers arranged to cooperate with each other to better guide, in translation as in rotation, the elongated flexible medical instrument, and thus prevent this elongated flexible medical instrument from slipping too much during of some of its movements, which otherwise would risk amplifying the effect of slack. To improve the guiding, in translation as in rotation, the elongated flexible medical instrument, it is proposed the use of at least three rollers arranged in a triangle so as to form a baffle for the elongated flexible medical instrument. Thus, this pebble triangle makes a chicane for the elongated flexible medical instrument. Advantageously, the rollers of this set of rotating rollers are arranged so as to cooperate with each other in order to better guide, in translation as well as in rotation, also the guide, and thus to prevent this guide from slipping too much during certain of its displacements. otherwise it may amplify the slack effect. To improve the guiding, in translation as in rotation, of the guide, it is proposed the use of at least three rollers arranged in a triangle so as to form a baffle for the guide. Thus, this triangle of pebbles makes a chicane for the guide. The improvements made to this set of rotating rollers in the rest of the text, which are valid for the catheter, can also be of advantage for the guide. To this end, this seventh object of the invention proposes an elongated flexible medical instrument drive module of an elongated flexible medical instrument insertion robot, comprising at least three rotary rollers, and preferably only three rollers. rotary, and movable relative to each other, so as to be closer to each other, so as to form a chicane between them during the passage of the elongated flexible medical instrument.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, at least one of the three rollers is a drive motor roller, and preferably only one of the three rollers is a drive motor roller.
Thus, the game of rollers does not need additional element of training while requiring only a limited drive system, since it is then sufficient to drive one of the three rollers.
Preferably, the axes of rotation of the rotary rollers are parallel to each other and the rollers are circular in a plane perpendicular to their axes of rotation.
Thus, the baffle remains symmetrical around the elongated flexible medical instrument, which prevents the elongated flexible medical instrument from being too tight on one side and not tight enough on the other side at a time during the crossing of the baffle, which allows to better guide the elongated flexible medical instrument, and the realization of this baffle is also made easier.
Preferably, the peripheries of two rollers are tangent to the periphery of a third roller.
Thus, the direction of the elongated flexible medical instrument remains the same at the exit of the chicane at the entrance of the chicane.
Preferably, the third roller has a greater diameter than those of the other two rollers.
Thus, the length of the elongated flexible medical instrument that is pressed against at least the surface of a roller is increased, which increases the guided length of the elongated flexible medical instrument, and which improves the guidance of the instrument. flexible medical elongated.
Preferably, the third roller is a drive roller of the elongate flexible medical instrument, while the other two rollers are pressure rollers of the flexible medical instrument elongated against the third drive roller.
Thus, it is sufficient to directly drive a single roller on all three, and as this third roller is the largest, it will more easily transmit the drive to two other rollers which are smaller.
Preferably, these two other rollers have the same diameter between them.
Thus, a symmetry of the baffle is respected between the entrance of the baffle and the exit of the baffle, which further improves the guiding of the elongated flexible medical instrument.
Preferably, in a plane perpendicular to the axes of rotation of the rollers, the angle from which the apex is the center of the third roller and which is formed by the two straight lines respectively connecting the centers of the two other rollers to the center of the third roller, is between 60 degrees and 120 degrees, and is advantageously about 90 degrees.
Thus, the amplitude of the changes of direction undergone by the elongated flexible medical instrument during its crossing of the chicane remains moderate and does not risk exerting too much stress on the elongated flexible medical instrument.
Preferably, at least the third roller and preferably also the other two rollers, have a concave slice of centered guide of the elongate flexible medical instrument.
Thus, the guidance of the elongated flexible medical instrument is further improved, since the elongated flexible medical instrument remains in the same plane, or at least tends to return to it as soon as it leaves, throughout its life. crossing the chicane.
Preferably, the concavity of this slice is between one quarter and three quarters of the diameter of the elongated flexible medical instrument, advantageously being half the diameter of the elongated flexible medical instrument.
Thus, this guidance of the elongated flexible medical instrument is, on the one hand, very effective in keeping the elongated flexible medical instrument centered during its crossing of the chicane, and, on the other hand, exerts no undue stress which would have the consequence risk of damaging the elongated flexible medical instrument or disrupting its operation.
Preferably, the elongated flexible medical instrument drive system comprises an elongated flexible flexible medical instrument insertion robot elongated medical instrument drive module according to the invention, an elongated flexible medical instrument passing through the baffle formed by the pebbles.
Preferably, the elongated flexible medical instrument is a catheter and / or guide.
An eighth object of the invention relates to a remote control cockpit of an elongated flexible medical instrument insertion robot that allows the practitioner to have the necessary visibility and the time necessary to guide the elongated flexible medical instrument despite a potential increased softness, while effectively protecting it during the entire handling time of this elongated flexible medical instrument. As a function of the different sizes and morphologies of the practitioner and the patient, as well as the different sizes and shapes of the apparatuses used, this eighth object of the invention proposes a global system that can be modulated, that is to say a protective screen which separated from the control station. To this end, this eighth object of the invention proposes a remote control cockpit of an elongated flexible medical instrument insertion robot comprising: a control station of said elongated flexible medical instrument insertion robot, without an integrated screen protection against X-rays, an X-ray shield, independent of said control station.
According to preferred embodiments, the invention comprises one or more of the following features which can be used separately or in partial combination with each other or in total combination with each other, not only with the object of the invention mentioned above, but also with all the objects of the invention mentioned in the remainder of the patent application.
Preferably, said protective screen is movable on the ground, preferably said protective screen rolls on the ground.
Thus, the overall modularity of the system is increased, the decoupling between the relatively sedentary control station if not completely immobile and the easily movable protection screen being increased.
Preferably, said control station is movable on the ground, preferably said control station rolls on the ground.
Thus, the complete mobility of the protection screen and the control station, as well as their total relative independence, allow an optimal modularity of the cockpit.
Preferably, said protective screen is transparent to visible light on at least a portion of its surface, preferably over its entire width, and over more than half of its height.
Thus, the visibility for the practitioner is increased, while maintaining a robustness and a reasonable manufacturing cost.
Preferably, said protective screen is in one piece.
Thus, the delicate problem of the protective function at the joints and joints, to limit or eliminate radiation leakage, is simply avoided.
Preferably, said protection screen comprises at least two planes not parallel to each other.
Thus, the trade-off between protection efficiency and overall dimensions of the protection screen is improved.
Preferably, said protective screen comprises all or part of the following elements: a glazed area, transparent to visible light, an area opaque to visible light, casters with brakes, several handles arranged so as to allow a single person to rolling the protection screen on the ground, preferably means for attaching display screens, such as, for example, angiography image duplication screens provided with height and / or width adjustment means, preferably cable catching means.
Preferably, said control station comprises all or part of the following elements: casters with brakes, at least one control member, preferably a joystick, at least one control screen, preferably a liquid crystal screen, preferably a touch screen screen, least another man-machine interface, comprising buttons and / or LED preferably LEDs, preferably accessories hooks, said accessories can be for example a remote control of injection of contrast medium, a control box d an examination table and / or an angiograph arch, a balloon inflator.
Preferably, the elongated flexible medical instrument is a catheter and / or guide. Other features and advantages of the invention will appear on reading the following description of a preferred embodiment of the invention, given by way of example and with reference to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
Throughout the rest of the detailed description, the elongated flexible medical instrument will be a catheter, but it may also be a guide or another type of elongated flexible medical instrument.
Figure 1A schematically illustrates an example of a catheter insertion robot portion comprising a rail attached to an arm with a motorized drive module according to an embodiment of the invention.
FIG. 1B diagrammatically shows a front view of an exemplary detail of interaction between the rail and the drive module in the insertion robot of FIG. 1A according to one embodiment of the invention.
Figure IC schematically shows a profile view of an example of interaction detail between the rail and the drive module in the insertion robot of Figure IA according to one embodiment of the invention.
FIGS. 1D to 1F schematically show front views of several examples of covers holding the catheter in the rail outside the passage area of the drive module for an insertion robot of FIG. embodiment of the invention.
FIG. 2 schematically represents an example of a catheter insertion robot portion comprising a sliding drive module on a motorized rail supported by an arm according to one embodiment of the invention.
Figures 3A and 3B schematically show respectively a side view and a front view of a first example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
FIG. 3B 'schematically represents an orthogonal profile view in view of FIG. 3A of the first example of a sterile barrier in a catheter insertion robot according to one embodiment of the invention.
FIGS. 3C and 3D schematically represent two front views, respectively outside the passage zone of the drive module and at the level of the passage zone of the drive module, of a second example of a sterile barrier in a robot of FIG. catheter insertion according to one embodiment of the invention.
Figure 3E schematically shows a profile view, at the passage area of the drive module, of a second example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
Figures 3 F and 3 G schematically show respectively a perspective view and a front view of a third example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
Figure 3H schematically shows a side view of a fourth example of a sterile barrier in a catheter insertion robot according to one embodiment of the invention.
Figure 31 schematically shows a side view of a fifth example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
Figure 3J schematically shows a side view of a sixth example of a sterile barrier in a catheter insertion robot according to one embodiment of the invention.
Figure 3K schematically shows a side view of a seventh example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
Figure 4A schematically shows a perspective view of a first example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figs. 4B-4C schematically show respectively front views of two alternatives of the first exemplary catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figure 4D schematically shows a perspective view of a second example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
Figure 4E schematically shows a perspective view of a third example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
Fig. 4F schematically shows a perspective view of a fourth example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figures 4G and 4H schematically show respectively front views of two open and closed positions of the fourth example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
Fig. 41 schematically shows a perspective view of a fifth example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
Figure 4J schematically shows a perspective view of a sixth example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figure 4K schematically shows a perspective view of a seventh example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figure 4L schematically shows a perspective view of an eighth example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figure 4M schematically shows a perspective view of a ninth example catheter guide track in a catheter insertion robot according to one embodiment of the invention.
Figure 5A schematically shows a side view of a first example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
Figure 5B schematically shows a side view of a second example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
Figure 5C schematically shows a side view of a third example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
Figure 5D schematically shows a side view of a fourth example of an arm supporting a catheter drive module in a catheter insertion robot according to one embodiment of the invention.
Figure 5E schematically shows a side view of a fifth example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
Figs. 5F and 5G schematically show respectively perspective views of a sixth example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
Figs. 6A and 6B schematically show perspective views, respectively in an assembled position and in a separate position, of an exemplary arterial introducer connector in a catheter insertion robot according to one embodiment of the invention. .
Figs. 7A and 7B schematically show top views of an example of a guide roller set of a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
Fig. 7C schematically shows a side view of an exemplary drive roller of a set of guide rollers of a catheter drive module in a catheter insertion robot according to an embodiment of the invention. 'invention.
FIG. 8A schematically represents a profile view of an exemplary remote control station of a catheter drive module in a catheter insertion robot, incorporating an antiradiation shield, according to an embodiment of the invention. invention.
FIG. 8B schematically shows a perspective view of another exemplary remote control station of a catheter drive module in a catheter insertion robot, incorporating a radiation shield, according to an embodiment of the invention. 'invention.
LIST OF REFERENCES IN FIGURES 1 / catheter 2 / guide 3 / drive module 4 / rail of the drive module 5 / arm (robotic) 6 / sterile barrier 7 / table 8 / arterial introducer (or valve) 9 / patient 10 / adjustment rail 11 / column 12 / ball joint 13 / fixed attachment 14 / motor part of the drive module 15 / support portion of the drive module 16 / power supply cable 17 / protuberances of the module support part drive 18 / grooves of the drive module rail 19 / groove cover 30 / crimped part 31 / holding elastic 32 / folding 33 / skirt for drive module 34 / winding 35 / fixing point 36 / cover 37 / glued skirt 38 / ballast 39 / stem of the drive module 40 / guide track 41 / chain 42 / flap 43 / split tube 44 / junction 45 / zip 46 / spiral 48 / winder 49 / band 50 / segment 51 / articulation 52 / stem 53 / anchor 54 / adjusting arm 60 / fitting 61 / guide tube 62 / connecting piece 63 / central clip 64 / side clip 65 / sleeve 66 / groove 67 / side opening 68 / female "luer-lock" junction 69 / hinge 70 / baffle 71 / drive roller 72 / periphery of roller drive 73 / pressure roller 74 / periphery of pressure roller 75 / guiding slice 80 / screen 81 / window portion of screen 82 / opaque portion of screen 83 / roller support 84 / control panel 85 / chair 86 / doctor 87 / lateral tube connected to the arterial introducer 88 / longitudinal openings of the connection 100 / front part of the distance of the drive module 101 / rear part of the distance of the drive module 102 / ground 160 / handles sterile barrier 180 / roll 190 / cap 191 / clip 192 / guide tab 400 / profile 401 / bottom 402 / spar 403 / lock 404 / lock 405 / attenuation 406 / bevel edge 407 / recess 410 / half chain slots 411 / slots 41 2 / bellows 413/414 fold / 801 blind / 802 display screens / 803 grip handles / 804 rollers / 805 rollers brakes / first 806 safety shield / protection plate 840 shield 841 Casters / 842 Casters / 843 Casters Brakes / 844 Control Office Casters / 845 Control Desk Workbench / 846 Control Panels / 847 Control Pads / Accessory Patches
DETAILED DESCRIPTION OF THE INVENTION
Figure 1A schematically illustrates an example of a catheter insertion robot portion comprising a rail attached to an arm with a motorized drive module according to an embodiment of the invention.
On a table 7 is fixed an adjustment rail 10. On this adjustment rail 10 moves horizontally a column 11. This vertical column 11 is secured to the adjustment rail 10 by its lower end and is vertically extensible. An arm 5 with two branches is secured to the upper end of the column 11 via a ball joint 12. Each of the branches of the arm 5 is fixed to a rail 4 of the drive module 3 by a fixed fastener 13. Along this rail 4 moves a drive module 3 which slides on this rail 4. The drive module 3 is composed of two parts, a motor portion 14 of the drive module 3 and a support portion 15 3. It is the support portion 15 of the drive module 3 which is in contact with the rail 4 and which slides on the rail 4 when the drive module 3 slides on the rail 4. The part motor 14 of the drive module 3 is supplied with power by a power supply cable 16. A catheter 1 is connected to or connected to the support portion 15 of the drive module 3.
A first sterile barrier 6 surrounds the adjustment rail 10, the column 11, the arm 5. A second sterile barrier 6 surrounds the motor portion 14 of the drive module 3, passing between the motor portion 14 and the support portion 15 of the module 3. These two sterile barriers 6 surround the reusable elements. Between these two sterile barriers 6 are the rail 4 with its fixed fasteners 13, as well as the support portion 15 of the drive module 3 and the catheter 1. First, the column 11 slides on the adjustment rail 10 until to arrive at the desired position, determined by the position of the patient on the table 7 as well as by the position of the arterial introducer corresponding to the point of entry of the catheter 1 in the patient. Once found this position of adjustment of the column 11 along the adjustment rail 10, this adjustment position is locked, and the column 11 becomes immobile in translation along the adjustment rail 10. Then, the column 11 is vertically extended until the correct height, for example telescopically. Once the correct column height 11 obtained, this height is locked. Finally, the ball joint 12 makes it possible to obtain the desired orientation for the arm 5 carrying the rail 4 and the drive module 3. Once this orientation has been obtained, it is locked to freeze this good orientation, which is well adapted to the input of the catheter 1 in the arterial introducer already set up on the patient. The rail 4 is fixed to the arm 5 by the fixed fasteners 13. Finally, the drive module 3 slides on the rail 4, passing from the dotted end position in FIG. 1A to a middle position in solid lines, pulling the catheter 1 and introducing it into the patient by passing it through the arterial introducer.
The rail 4 is in disposable aluminum profile. To reduce the size of this rail 4, it could be delivered in several pieces and then assembled. This would also simplify its disposal.
The motor part 14 of the rail 4 is a reusable and motorized trolley. It accommodates the block of the drive module 3. This drive module 3 accommodates the catheter 1 and the guide 2. The advance of the catheter 1 is achieved by the movement of the motor part 14 along the rail 4, while the rotation is effected by a mechanism forming part of the drive module 3. The guide 2 is driven, in translation and in rotation, by means of the drive module 3.
The column 11 could also perform a rocking movement to bring the end of the rail 4 closer to the patient and thus reduce the dead length. For this purpose a screw system would be used. A crank would then be installed at the end of the screw to facilitate its use. To adjust its height in order to adapt to the different morphologies of patients, the column f is for example telescopic, and operated via a crank, placed on its lower part. A worm system coupled to a guide shaft then ensures the displacement.
The linear rail 10 allows pre-positioning of the assembly before the start of the operation. H is equipped with two handles, one with a touch. This key will be used to disengage a brake system or notches, to manually move the entire arm 5 relative to the linear rail 10. This linear rail 10 is attached and independent of the DIN rail of the table 7.
FIG. 1B diagrammatically shows a front view of an exemplary detail of interaction between the rail and the drive module in the insertion robot of FIG. 1A according to one embodiment of the invention.
The second sterility barrier 6 passes between the motor portion 14 and the support portion 15 of the drive module 3. The drive module 3 is hooked on the rail 4 via its support portion 15. The support portion 15 of the drive module 3 comprises three protuberances 17 giving inside this support portion 15 an E-shape. These three protuberances 17 fit into three grooves 18 of the rail 4 and cooperate with these three grooves 18 to slide in these three grooves 18, for example by rolling on rollers 180 arranged at the bottom of these grooves 18. These rollers 180 are advantageously mounted on the consumable portion 15 of the drive module 3.
The support portion 15 of the drive module 3 has an E-shape for sliding in three of the grooves 18 of the rail 4 being driven by rollers 180. Several pads, including some pressers, could be added to hold in position the assembly. . The grooves 18 of the rail 4 could also serve as tracks for the catheter 1 and / or a guide 2. In this case, a cover 19 is advantageously installed as shown in Figures 1C to 1F.
Figure IC schematically shows a profile view of an example of interaction detail between the rail and the drive module in the insertion robot of Figure IA according to one embodiment of the invention.
The direction of movement of the drive module 3 is given by the arrow. When moving the drive module 3 along the rail 4, a front portion 100 of the distance of the drive module 3 lifts the cover 19 covering the groove 18 of the rail 4 to let the drive module 3, and a rear portion 101 lowers the cover 19 to cover again the groove 18 of the rail 4 after the passage of the drive module 3. Thus the cover 19 is not raised or is not spaced, according to the embodiments, that at the time of the passage of the drive module 3, which limits the risk of seeing dust fall into the groove 18 of the rail 4 where the catheter 1 passes.
FIGS. 1D to 1F schematically show front views of several examples of covers holding the catheter in the rail outside the passage area of the drive module for an insertion robot of FIG. embodiment of the invention.
In FIG. 1D, in a first embodiment, at the bottom of a groove 18 of the rail 4, progresses the catheter 1, driven by the displacement of the drive module 3. A cover 19 covers the catheter 1 in the groove 18. This cover 19 comprises a cap 190 extended on each side by a clip 191 to fit the cover 19 into the groove 18 to form a protective channel for the catheter 1.
In FIG. 1E, in a second embodiment, at the bottom of a groove 18 of the rail 4, progresses the catheter 1, driven by the displacement of the drive module 3. A cover 19 covers the catheter 1 in the groove 18. This cover 19 comprises a cap 190 extended on each side by a clip 191 to fit the cover 19 in the groove 18 to form a protective channel for the catheter 1. Each clip 191 is in turn extended by a guide tab 192, the catheter 1 being held between the two guide tabs 192.
In FIG. 1F, in a third embodiment, at the bottom of a groove 18 of the rail 4, progresses the catheter 1, pulled by the displacement of the drive module 3. A cover 19 covers the catheter 1 in the groove 18. This cover 19 includes a cap 190 extended on each side by a clip 191, at each end of the cap 190, for fitting the cover 19 into the groove 18 to form a protective channel for the catheter 1. The cap 190 is extended on each side by a guide tab 192, at each middle portion of the cap 190, to maintain the catheter 1 between the two guide tabs 192.
FIG. 2 schematically represents an example of a catheter insertion robot portion comprising a sliding drive module on a motorized rail supported by an arm according to one embodiment of the invention.
A patient 9 rests on a table 7. An arm 5 is disposed on this table 7. At the level of a member of a patient 9, for example at the level of the leg or the arm of a patient 9, has been arranged an arterial introducer 8. A catheter 1 is gradually introduced into this arterial introducer 8. The arm 5 carries the rail 4. The drive module 3 drives the catheter 1 to introduce it into the arterial introducer 8, by sliding on the rail 4. The motorization is provided by the rail 4 which is motorized and which drives the drive module 3 which is not motorized.
The rail 4 is carried by a mechanical arm 5 connected to the table 7. This mechanical arm 5 has several degrees of freedom to approach the end of the rail 4 closest to the patient 9.
Then, the drive module supports the catheter 1 and the guide 2. It ensures the rotation of the catheter 1 and the translation and rotation of the guide 2, the translation of the catheter 1 being in turn carried out by the movement of the catheter 1. drive module 3 along the rail 4.
Figures 3A and 3B schematically show respectively a side view and a front view of a first example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
In the text, unless otherwise stated, we speak indifferently of sterile skirt or sterile barrier.
In FIG. 3A, the drive module 3 can slide from one side to the other of the rail 4, and vice versa. The sterile barrier 6 extends over the entire length of the rail 4, passing in the middle of the drive module 3 between its motor portion 14 and its support portion 15. Here, the motor portion 14 is on the side of the rail 4 which is motorized and which drives the motor part 14. Here, the actual engine is rather the rail side 4 than the drive module side 3. The motor portion 14 is reusable, the support portion 15 is against cons single use. On each side of the drive module 3, the sterile barrier 6 comprises a wrinkled portion 30 which may at will stretch or compress, depending on whether the movement of the drive module is in one direction or the other. Indeed, one of the wrinkled parts 30 compresses when the drive module 3 pushes it while the other wrinkled part 30 stretches simultaneously since the drive module 3 pulls it, and then vice versa.
In FIG. 3B, the sterile barrier 6 covers the rail 4 from underneath, and maintains the wrinkled parts 30 around the rail 4 by means of elastics 31 of support arranged on each side transversely to the direction of the rail 4.
FIG. 3B 'schematically represents a profile view orthogonal to the view of FIG. 3A, of the first example of a sterile barrier in a catheter insertion robot according to one embodiment of the invention. The sterile barrier 6 is shown alone with the support portion 15 of the drive module 3, in a folded configuration. On each side longitudinally, with respect to the rail 4 not shown, is the wrinkled portion 30 of the sterile barrier 6 in folded configuration. At the end, opposite to the support portion 15, of each wrinkled portion 30, there is a handle 160, assisting by traction on unfolding the sterile barrier 6 and installing it around the rail 4.
The skirt 6 is wrinkled on both sides of the drive module 3, and to maintain these wrinkled parts 30 and to prevent the skirt 6 comes to touch the catheter 1 or any other external element, elastics 31 have been added on each side of the rail 4. The crumpled portions 30 allow the translations of the drive module 3 to be accommodated along the rail 4.
FIGS. 3C and 3D schematically represent two front views, respectively outside the passage zone of the drive module and at the level of the passage zone of the drive module, of a second example of a sterile barrier in a robot of FIG. catheter insertion according to one embodiment of the invention.
In FIG. 3C, the rail 4 is surrounded by the sterile barrier 6, two folds 32 coming one over the other to cover the upper part of the rail 4. FIG. 3C represents the configuration of the sterile barrier 6 surrounding the rail 4, on the portions of the rail 4 where the drive module 3 is not located.
In FIG. 3D, the rail 4 is surrounded by the sterile barrier 6, two folds 32 coming from one another to punctually no longer cover the upper part of the rail 4 and to allow the drive module to pass on the contrary. 3. FIG. 3D represents the configuration of the sterile barrier 6 only partially surrounding the rail 4, on the portion of the rail 4 where the drive module 3 is located.
The split skirt 6 opens to the passage of the drive module 3, and once it is open, its design in "gutter" allows to maintain sterility.
Figure 3E schematically shows a profile view, at the passage area of the drive module, of a second example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
The front portion 100 spacing of the drive module 3, as it passes, separates the two folds 32 which were in the folded configuration of Figure 3C to put them in the unfolded configuration of Figure 3D, before the part rearward 101 of the drive module 3 (not shown here) does not return them in the folded configuration of Figure 3C.
Figures 3F and 3G schematically show respectively a perspective view and a front view of a third example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
In FIG. 3F, a first sterile barrier 6 surrounds the rail 4, the sterile barrier 6 being non-movable with respect to the rail 4, while a second sterile barrier 33 surrounds the drive module 3. This first sterile barrier 6 is not movable relative to the rail 4. The drive module 3 slides under the rail 4 to which it is attached. A slot in the sterile barrier 6 allows to pass for example a support bracket of the drive module 3, while limiting the risk of rising contamination.
FIG. 3G shows the holding elastics 31 of the first sterile barrier 6 surrounding the rail 4. During sliding of the drive module 3 under the rail 4, the first sterile barrier 6 opens between the two elastics of holding 31 to pass the drive module 3 and closes after its passage.
Preferably, the rail 4 which is in fact in the opposite position, that is to say with its moving part downwards, comprises a bracket 39 on which will be fixed the drive module 3. The drive module 3 and the stem will be covered with a blister 33 which fits perfectly the shape of the drive module 3 and its bracket 39. The rail 4 is provided with a charlotte 6 with a resilient 31 which will tighten around itself.
Figure 3H schematically shows a side view of a fourth example of a sterile barrier in a catheter insertion robot according to one embodiment of the invention.
The drive module 3 comprises two reels 34, one on each side longitudinally with respect to the drive module 3, one at the front and the other at the rear. The sterile barrier 6, which surrounds the rail 4, is fixed to the rail 4 by means of two fixing points 35 located at the two ends, in the longitudinal direction, of the rail 4. When the drive module 3 moves through on one side, the reel 34 which is located at the front of the drive module 3 with respect to its movement, "swallows" the sterile barrier 6 as the drive module 3 moves, until the to arrive in the vicinity of one of the attachment points 35, while the other retractor 34 which is located at the rear of the drive module 3 with respect to its movement, "unrolls" the sterile barrier 6 as as the drive module 3 moves away from the other attachment point 35. When the drive module 3 leaves on the other side, the reel 34 which is located at the front of the module training 3 in relation to its displacement, "swallows" the sterile barrier 6 as the displacement of the drive module 3, until reaching the vicinity of one of the attachment points 35, while the other winder 34 which is located at the rear of the module 3 relative to its movement, "unrolls" the sterile barrier 6, which it had swallowed in the previous step, as and when the displacement of the drive module 3 away from the other point fixing 35.
Figure 31 schematically shows a side view of a fifth example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
The sterile barrier 6 is smooth and has a great length, typically about twice the length of the rail 4. At one of the longitudinal ends of the rail 4 is a hood 36 bent down and located above the rail 4. The sterile barrier 6, when pushed by the drive module 3 in the direction of the cover 36, will be deflected by the cover 36 downwards and thus will slide between this cover 36 and the rail 4. Conversely when the drive module 3 moves in the other direction, a significant excess of sterile barrier length 6 is found to hang beyond the rail 4.
The skirt 6 is long enough to accommodate the movements of the drive module 3, advantageously at least twice the stroke of the rail 4. A cap 36 is placed on the side of the arterial introducer (or vest) to direct the skirt 6 to down, and thus out of the area of this arterial introducer for safety reasons. In this configuration, the drive module can be positioned on the top of the rail 4, or underneath the rail 4, or else laterally with respect to the rail 4.
Figure 3J schematically shows a side view of a sixth example of a sterile barrier in a catheter insertion robot according to one embodiment of the invention.
In addition to the sterile barrier 6 covering the rail 4 and passing through the drive module 3, thus separating the support portions 15 and motor 14 of the drive module 3, another sterile skirt 37, located under the sterile barrier 6, covers closest rail 4, being placed on the rail 4, and preferably being glued on the rail 4, without integrating any portion of the drive module 3. This double sterile protection improves the level of protection, it however requires the use of two sterile skirts of different sizes and shapes.
Figure 3K schematically shows a side view of a seventh example of a sterile barrier in a catheter insertion robot according to an embodiment of the invention.
The sterile barrier 6 makes the complete turn of the rail 4, but transversely, that is to say around an axis perpendicular to the longitudinal axis of the rail 4, and not around the longitudinal axis of the rail 4 as in other embodiments. This sterile barrier 6 comprises weights 38, to prevent the free part of the sterile barrier 6, which is not around the rail 4, come to interfere with the rest of the device. As the drive module 3 moves, the sterile barrier 6 rotates about an axis perpendicular to the longitudinal axis of the rail 4, in the direction shown by the arrows shown in FIG. 3K.
The skirt 6 is thus rotated around the rail 4 when the drive module 3 moves. The ballast 38 in the skirt 6 ensures that it falls properly and does not interfere with the mechanism located above it. Another solution would be to add guiding flanges on the sides to not interfere with the external elements, taking care to ensure the tightness of these flanges.
Figure 4A schematically shows a perspective view of a first example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
A chain 41, of the "cable holder chain" type, delimits within its structure, a guide track 40 in which a catheter 1 and a guide 2, shown only in Figures 4B and 4C, will be guided.
Figs. 4B-4C schematically show respectively front views of two alternatives of the first exemplary catheter guide track in a catheter insertion robot according to one embodiment of the invention. This guideway of the catheter can also be used to guide a guide.
In the first example of Figure 4B, a catheter 1 is introduced into the guide track 40, through the space between the flaps 42 flexible. This space is smaller than the diameter of the catheter 1 which pushes the flaps 42 inwardly during its introduction into the guide track 40, these flaps 42 elastically and automatically resetting their horizontal position after the passage of the catheter 1.
In the second example of Figure 4C, two possible positions of the catheter 1 are shown with respect to the guide track 40. The catheter 1 is introduced into the guide track 40 through the space between the flaps 42 flexible. This space is smaller than the diameter of the catheter 1, which pushes the flaps 42 inwards during its introduction into the guide track 40, these flaps 42 elastically and automatically resetting their oblique position after the passage of the catheter 1.
Figure 4D schematically shows a perspective view of a second example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
The guide track 40 is constituted by the inside of a split tube 43, which opens to let a catheter 1 pass and which closes after the passage of this catheter 1, at a junction 44.
Figure 4E schematically shows a perspective view of a third example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
The guide track 40 is a channel that will receive a catheter 1 after passing through a zip closure 45 joining two flaps 42 horizontal. During the introduction of this catheter 1 into the guide track 40, the zip closure 45 opens to allow this catheter 1 to pass and then closes again after the passage of this catheter 1.
Fig. 4F schematically shows a perspective view of a fourth example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
The catheter 1 is guided in a section 400, which opens to allow the catheter 1 to pass inside the profile 400, then which closes after the passage of the catheter 1 to guide it inside the profile 400. section 400 is opened by a front portion 100 of the drive module 3 and is closed by a rear portion of the drive module 3.
Figures 4G and 4H schematically show respectively front views of two open and closed positions of the fourth example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
In FIG. 4G, the profile 400 is in the open position to allow a catheter 1 to pass when it is introduced into the profile 400. The profile 400 comprises a bottom 401, two longitudinal members 402, a female closure 403, a male closure 404, two 405, four bevelled edges 406, two enlarged cavities 407. The bevelled edges 406 are divided into two pairs, one on each side of the bottom 401, and for each pair, one of the bevelled edges 406 is on the spar 402, while that the other is on the bottom 401. Between the bevelled edges 406 of each pair and the corresponding attenuation 405 is an enlarged cavity 407 further improving the flexibility of the weakening 405 while making it more robust since the surface of 405 attenuation being increased, the effort that will be exerted on it will be better distributed.
The bottom 401, of rounded shape, is connected by its two ends respectively to the longitudinal members 402, respectively via the weakens 405. One of the longitudinal members 402 carries the male closure 404, while the other longitudinal member 402 carries the closure female 403.
The male closure 404 is out of the female closure 403. Their respective longitudinal members 402 have moved away from each other by deforming their weakenings 405 which are intrinsically more flexible parts than the others in the section 400 because of their weak thickness. The beveled edges 406 of each pair have also moved apart from each other.
In FIG. 4H, the profile 400 is in the closed position to guide a catheter 1.
The male closure 404 is retracted into the female closure 403. Their respective longitudinal members 402 have moved closer to each other and have become parallel again constituting the side walls of the guide track 40. The bevelled edges 406 of each pair are also close together, until they come into close contact with each other. The guide track 40 now forms a channel whose inner wall is almost continuous.
Fig. 41 schematically shows a perspective view of a fifth example of a catheter guide track in a catheter insertion robot according to an embodiment of the invention.
The guide track 40 is a spiral 46 between the turns of which the catheter 1 is inserted to be guided and moved by the rotation of the spiral 46 about its own axis of symmetry.
Figure 4J schematically shows a perspective view of a sixth example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
The guide track 40 is located between strips 49 which are wound or unwound from reels 48. When the drive module 3 moves to the reels 48 by pushing a catheter 1 (not shown) into the guide track 40, as the progress of the drive module 3 to an arterial introducer, the strips 49 wind up in the reels 48.
The two reels 48 which are placed closest to the arterial introducer each contain part of the "zip" system. At the exit of the reels 48, the two bands 49 which are the two parts of the zip join to form a single wide band. The end of this wide band is secured to the drive module 3.
Figure 4K schematically shows a perspective view of a seventh example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
The guide track 40 is the inside of a chain formed by the assembly of two half-chains 410 which fit into one another through their respective slots 411 complementary to each other.
The chain is formed of two flexible parts which are the half-chains 410 and which, once the half-chains 410 joined together by fitting one into the other, stiffens and keeps the catheter 1 in place.
Figure 4L schematically shows a perspective view of an eighth example of a catheter guide track in a catheter insertion robot according to one embodiment of the invention.
The guide track 40 is the interior of a bellows 412 comprising a number of turns 413. This bellows 412 can be compressed or extend in the direction of movement of the drive module 3. This bellows 412 covers the track guide 40 from above.
Figure 4M schematically shows a perspective view of a ninth example catheter guide track in a catheter insertion robot according to one embodiment of the invention.
The guide track 40 of the catheter 1 is constituted by a channel covered by a blind 414. Depending on the direction of movement of the drive module 3, the blind 414 is wound in the reel 48 or is rolled out from the winder 48, so as to cover the portion of the guide track 40 between the drive module 3 and the arterial introducer.
Figure 5A schematically shows a side view of a first example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
The catheter drive system of a catheter insertion robot comprises an articulated arm comprising at least three segments 50, here four segments 50, hinged together by hinges 51, advantageously ball joints or at least pivot links. This robotic arm is adapted to describe a linear path in space at its distal end which carries a catheter drive module 3 secured to this distal end.
In the order from the patient to the table 7, there is the drive module 3 carried by a first segment 50 at the distal end of the arm 5, a second segment 50, a third segment 50, a fourth segment. segment 50 connected at its proximal end to an adjusting rail 10. The distal end of the arm 5 is its patient side end while the proximal end of the arm 5 is its table end 7.
Once the proximal end of the arm 5 immobilized along the adjustment rail 10 relative to the size and position of the patient and with respect to the arrangement of the arterial introducer at the patient, the different segments 50 s articulate with each other so as to make the driving module 3 traverse a linear trajectory so as to introduce the catheter into the arterial introducer by means of a linear displacement of the drive module 3.
The adjustment phase is effected by the displacement of the arm 5 as a whole along the adjustment rail 10, whereas the phase of displacement of the driving module 3 is effected by the deployment of the arm 5, the segments 50 of which articulate. around the joints 51.
The robotic arm being mounted on an adjusting rail 10 itself fixed at the table edge 7, the adjustment of the drive system with respect to the finishing point is effected by means of the adjustment rail 10, manually by the user, then the locking of the chosen position is performed. The position of the robotic arm 5 being then fixed, it will then only have to take over the trajectory zone corresponding to the progression of the catheter 1 in the patient.
Figure 5B schematically shows a side view of a second example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
The catheter insertion system of a catheter insertion robot comprises an articulated arm comprising three segments 50 articulated to each other by articulations 51, and robotized which is adapted to make a linear trajectory in the space to be described. its distal end which carries a catheter drive module 3 secured to this distal end.
In the order from the patient to the table 7, there is the drive module 3 carried by a first segment 50 at the distal end of the arm 5, a second segment 50, a third segment 50 directly connected to the level of its proximal end to the table 7 by a ball joint.
The different segments 50 articulate with each other to make the drive module 3 follow a linear trajectory so as to introduce the catheter into the arterial introducer by means of a linear displacement of the drive module 3.
The adjustment phase and the displacement phase of the drive module 3 are simultaneously performed by the deployment of the arm 5, the segments 50 of which articulate around the hinges 51. Alternatively, a part of the arm 5, situated on the end side proximal, could initially perform the adjustment phase, while another part of the arm 5, located on the side of its distal end, could then perform in a second phase the movement phase of the drive module 3 to introduce the catheter in the arterial introducer.
The pendulum robotic arm being fixed directly on the table 7, the use of an axis of rotation, located at the base of the arm 5, and its association with the segments 50 and their joints 51, make it possible to obtain that the distal end of the arm 5 carrying the drive module 3 follows a rectilinear trajectory when its proximal end at the base of the arm 5 is actuated in rotation. Such an arm 5 makes it possible to obtain a greater range of displacement, and thus it can take care of both the adjustment of the point of arrival of the catheter 1 and the trajectory area of the catheter 1.
Figure 5C schematically shows a side view of a third example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
The catheter insertion system of a catheter insertion robot comprises an articulated arm comprising three segments 50 articulated to each other by articulations 51, this arm being robotic and adapted to describe a linear trajectory in the space at its distal end which carries a catheter drive module 3 secured to this distal end. The realization of a position of the arm 5 in solid lines and another position of the arm 5 in dotted lines, illustrates the movement of the arm 5 and the drive module 3 from one position to the other.
In the order from the patient to the table 7, there is the drive module 3 carried by a first segment 50 at the distal end of the arm 5, a second segment 50, a third segment 50 connected to the level its end proximal to a bracket 52 itself sliding along an adjusting rail 10 disposed on the table 7. The bracket 52 comprises a vertical portion whose bottom slides in the adjustment rail 10 and a horizontal portion attached to one side at the top of the vertical portion and the other side at the proximal end of the arm 5.
Once the stem 52 immobilized along the adjustment rail 10 relative to the size and position of the patient and with respect to the arterial introducer arrangement at the patient, the different segments 50 articulate with each other. to make the drive module 3 do a linear trajectory so as to introduce the catheter into the arterial introducer by means of a linear displacement of the drive module 3.
The adjustment phase is carried out by the movement of the bracket 52 along the adjustment rail 10, while the phase of displacement of the drive module 3 is effected by the deployment of the arm 5 whose segments 50 are articulated around the joints 51.
The robotic arm 5 being pendulum but being hooked at the end of a bracket 52, the mobility of this bracket 52 makes it possible to ensure the adjustment of the arrival point of the catheter 1.
Figure 5D schematically shows a side view of a fourth example of an arm supporting a catheter drive module in a catheter insertion robot according to one embodiment of the invention.
The catheter drive system of a catheter insertion robot comprises an articulated arm comprising four segments 50 articulated to each other by articulations 51, which is robotic and which is adapted to describe a linear trajectory in the space at its distal end which carries a catheter drive module 3 secured to this distal end.
In the order from the patient to the table 7, there is the drive module 3 carried by a first segment 50 at the distal end of the arm 5, a second segment 50, a third segment 50, a fourth segment. segment 50 anchored in the ground 102 at an anchor 53, the fourth segment 50 being vertical.
The different segments 50 articulate with each other in order to describe to the drive module 3 a linear trajectory so as to introduce the catheter into the arterial introducer by means of a linear displacement of the drive module 3.
The adjustment phase and the displacement phase of the drive module 3 are simultaneously performed by the deployment of the arm 5, the segments 50 of which articulate around the hinges 51. Alternatively, a part of the arm 5, situated on the end side proximal, could initially perform the adjustment phase, while another part of the arm 5, located on the side of its distal end, could then perform in a second phase the movement phase of the drive module 3 to introduce the catheter in the arterial introducer.
The fully robotized arm 5 being placed on the ground 102, this drive system has freed the problem of attachment to the table 7, but at the expense of the need for the additional system for monitoring the movements of the table 7, allowing avoid that the table 7 is moved without the robotic arm.
Figure 5E schematically shows a side view of a fifth example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
The catheter drive system of a catheter insertion robot comprises an articulated arm comprising three segments 50 articulated to each other by articulations 51, this robotic arm being adapted to describe a linear trajectory in space. at its distal end which carries a catheter drive module 3 secured to this distal end. The realization of a position of the arm 5 in solid lines and another position of the arm 5 in dotted lines, illustrates the movement of the arm 5 and the drive module 3 from one position to the other.
In the order from the patient to the table 7, there is the drive module 3 carried by a first segment 50 at the distal end of the arm 5, a second segment 50, a third segment 50 connected to the level from its proximal end to a control arm 54 itself comprising several segments articulated with each other.
Once the adjustment arm 54 is immobilized in a required position with respect to the size and position of the patient as well as with respect to the arterial introducer arrangement at the patient, the different segments 50 articulate with each other for have the training module 3 describe a linear trajectory so as to introduce the catheter into the arterial introducer by means of a linear displacement of the drive module 3.
The adjustment phase is effected by the movement of the adjustment arm 54 as a whole, while the phase of displacement of the drive module 3 is effected by the deployment of the arm 5 whose segments 50 articulate around the articulations 51.
The robotic arm being pendulum and attached to an adjusting arm 54, it is this adjustment arm 54 which allows the adjustment of the arrival point of the catheter 1 relative to the arterial introducer. The seal between the consumable and non-consumable portion is provided by a sterile sock completely covering the robotic arm.
Figs. 5F and 5G schematically show respectively perspective views of a sixth example of an arm supporting a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
The catheter insertion system of a catheter insertion robot comprises an articulated arm comprising three segments 50 articulated to each other by articulations 51 which are pivotal links about the vertical axis Z, and robotic which is adapted to describe a linear and horizontal trajectory in the XY plane at its distal end which carries a catheter drive module 3 secured to this distal end.
In the order from the patient to the table 7, there is the drive module 3 carried by a first segment 50 at the distal end of the arm 5, a second segment 50, a third segment 50 connected to the level its end proximal to a column 11 adjustable in height, this column 11 itself being slidably mounted on a control rail not shown in these figures but similar to the adjustment rail 10 shown in Figure 5 A.
Once the column 11 is adjusted in height and immobilized along the adjustment rail 10 with respect to the size and the position of the patient as well as with respect to the arrangement of the arterial introducer at the level of the patient, the different segments 50 s articulate with each other so as to make the drive module 3 traverse a linear and horizontal trajectory so as to introduce the catheter into the arterial introducer by means of a linear displacement of the drive module 3.
The adjustment phase is carried out by the height adjustment and the displacement of the column 11 carrying the arm 5 along the adjustment rail 10, whereas the phase of displacement of the drive module 3 is carried out by the deployment of the arm 5. whose segments 50 articulate horizontally around the joints 51.
The drive module being carried by a motorized arm, consisting of several segments 50 articulating horizontally around the hinges 51, the translational movement of the drive module 3 is achieved by deploying the robotic arm 5 in a single horizontal plane. In this way, the masses to be moved for each part of the robotic arm are reduced. The forces applied to the robotic arm 5 will therefore be reduced, and it will be easier to detect a force at the level of the motorization of this robotic arm. The drive module 3 will be installed at the distal end of the robotic arm, therefore at the end opposite its proximal end connected to the column 11. This column 11 could also be installed on a control rail 10. This column 11 is then placed at a distance that makes it possible to make maximum advance and maximum retraction to the robotic arm during the operation. Column 11 remains in this case of course adjustable in height to accommodate the different morphologies of the patient.
Figs. 6A and 6B schematically show perspective views, respectively in an assembled position and in a separate position, of an exemplary arterial introducer connector in a catheter insertion robot according to one embodiment of the invention. .
The connector 60 comprises several parts 62. This connector 60 can be divided into several parts 62 in two ways, either on either side of a longitudinal plane as in FIG. 6A, or on either side of a transverse plane as in Figure 6B. On one longitudinal side of the connector 60 enters through a longitudinal opening 88, the guide tube 61 terminated by a female junction 68 type "luer-lock" going towards the drive module. The "luer-lock" type junction is defined in the standards ISO 594, EN 1707: 1996 and EN 20954-1: 1993. On the other longitudinal side of the connector 60 enters through a longitudinal opening 88, the arterial introducer 8 which is further connected to a lateral pipe 87 which enters through a lateral opening 67.
A sleeve 65 comprises a plurality of grooves for adjusting the length of the sleeve 65 penetrating into the connector 60 to ensure that the sleeve 65 advantageously comes into contact with the arterial introducer 8, and this, for different sizes and morphologies of arterial introducer. This contact makes it possible to ensure the continuity of the path of the catheter 1 coming from the guide tube 61 passing through the sleeve 65 and then entering the arterial introducer 8, and this, without the risk of forming a loop in the connection 60, between the outlet of the sleeve 65 and the entrance of the arterial introducer 8.
In FIG. 6A, the connector 60 is separated longitudinally into two parts 62 attached by hinges 69. By folding these two parts 62 one over the other, the connector 60 will close at the level of the lateral clips 64.
In FIG. 6B, the connector 60 is separated transversely into two parts 62. By bringing the two parts 62 closer together, the connector 60 will close at the level of the central clips 63. The central clips 63 must be able to reach each other. detach easily under the effect of a force or sudden stress caused by a sudden movement of the arm or another member of a patient, and in particular to be able to detach more easily than the side clips 64. The male part of the clip 63 is a disc which fits into the V-shaped female part widening in a circle towards the tip of the V. The male part of the clip 63 also comprises a lateral guiding flange for interlocking with the female part 63 clip.
In summary, the connector 60 is placed at the output of the drive module and allows the junction between the drive system and the arterial introducer 8. This connector 60 allows the rapid assembly of this junction on the arterial introducer 8 already in place, while serving as a guide for conveying the guide 2 (not shown in Figures 6A and 6B) and or the catheter 1 by preventing them from forming a loop in case of resistance to advance. This connection 60 is finally and above all a safety, if the patient had to move suddenly, because it allows the separation between the drive system and the patient without pulling on the introducer arterial 8.
This rapid assembly of the junction is then carried out as follows. The sleeve 65 is brought into close contact with the arterial introducer 8 already in place during the approach operation and manual implementation of the drive system. Then the two parts 62 of the connector 60 (as shown in Figure 6A), previously assembled are closed on the arterial introducer 8 and the sleeve 65 to ensure the relative maintenance.
In case of strong agitation of the patient, for example if it withdraws abruptly, to avoid the risk of injury of this patient, the central clips 63 of the two parts 62 of the connector 60 previously assembled together, will open ( as shown in Figure 6B) to allow the separation of its two parts 62 of connector 60 and thus release the patient of the drive system by applying a very limited effort on the arterial introducer 8.
Thus, the combination of the central clips 63 and lateral clips 64, with their respective tensile strengths, will allow a disconnection in case of accidental effort too important ensuring the safety of the patient and also a disconnection, this time non-accidental , in view of the introduction and withdrawal of the drive system, while the presence of the sleeve 65 will allow adaptation to different morphologies arterial introducer 8 and the guarantee of a good connection, that is to say that is to say a connection having only a limited empty space between the arterial introducer 8 and the sleeve 65.
Figs. 7A and 7B schematically show top views of an example of a guide roller set of a catheter drive module in a catheter insertion robot according to an embodiment of the invention.
The catheter drive module of a catheter insertion robot comprises three rotatable rollers 71 and 73 movable relative to each other, so as to be closer to each other, so as to form a baffle 70 between them during the passage of the catheter 1. The small rollers 73 have a periphery 74 and the large roller 71 has a periphery 72.
In FIG. 7A, the two small pressure rollers 73 and the large driving roller 71 have moved closer to each other and to the catheter 1. The periphery 74 of the small pressure rollers 73 tangentiates the periphery 72 of the large roller 71 by driving the catheter 1. The catheter 1 must first pass between the periphery 74 of a small pressure roller 73 and the periphery 72 of the large driving roller 71, then follow the periphery 72 of the large roller 71, then pass between the periphery 74 of the other small roller 73 and the periphery 72 of the large drive roller 71, before continuing in the same direction as its direction of arrival.
This course is the chicane 70 in which the catheter 1 arrives in a direction of arrival, changes direction, then replacement of direction, before leaving the chicane 70 in a direction of departure parallel to its direction of arrival, and even confused with his arrival direction. The large drive roller 71 drives the catheter 1 to advance it. The small pressure rollers 73 hold the catheter 1 against the large driving roller 71.
In FIG. 7B, the two small pressure rollers 73 and the large driving roller 71 have moved away from each other as well as from the catheter 1. The periphery 74 of the small pressure rollers 73 as well as the periphery 72 of the large roller 71 training no longer affects the catheter 1 which has returned to its fully linear direction. The chicane 70 has disappeared.
With the large drive roller 71 which is placed facing the two pressure rollers 72, the curvature generated on the guide 2 or on the catheter 1 by the position of these three rollers allows a good translation and a good rotation, thanks to a crank type effect. The entire system can be opened to allow the introduction of the element to be driven, the guide 2 or the catheter 1. This roller system has overall fewer elements than a belt system known to the prior art.
Fig. 7C schematically shows a side view of an exemplary drive roller of a set of guide rollers of a catheter drive module in a catheter insertion robot according to an embodiment of the invention. 'invention.
The two small pressure rollers 73 and the large driving roller 71 have a concave slice 75 of centric guide of the catheter 1. Thus, the catheter 1, as it passes through the baffle 70, remains guided in the center of the concave slices 75 of the rollers 71 and 73, and is no longer likely to exit the guide rollers 71 and 73.
FIG. 8A schematically represents a profile view of an exemplary remote control station of a catheter drive module in a catheter insertion robot, incorporating an antiradiation shield, according to an embodiment of the invention. invention.
This cockpit which is composed of two independent elements, namely on the one hand the control station still called control office 84 and secondly the protection screen 80, allows the user who is the doctor 86 to control the remote manipulator robot in an X-ray protected area during an intervention, for example in the angiography room.
The physician 86, seated on a chair 85, remotely controls the progression of the catheter in the patient from the control desk 84 which is deported relative to the patient lying on a table. In order to minimize the radiation supported by the physician 86, a shield 80 isolates the physician 86 from the table and from the patient. Indeed, it is critical to reduce the radiation received by the physician 86, because it is subject to it all day long, unlike a patient who will be subjected to it only during the time of its examination, and for which reducing radiation is important but less critical. The screen 80, independent of the control desk 84 as the table where the patient is lying, protects the doctor 86 from radiation because it is generally opaque to these radiations, usually X-rays. The screen 80 comprises an upper part. 81 and a lower part 82, both opaque to radiation. The upper part 81 is glazed, that is to say transparent to visible light, to allow the doctor 86 to monitor his patient from a distance. The lower part 82 is also opaque to visible light, thus being simpler to produce. The height of the lower part 82 is about 50cm. The screen 80 is mobile and mounted on wheels 83, so it can easily be moved in the room.
The fact that the protection screen 80 is independent of the control desk 84 optimizes its integration in the room, facilitating the passage of access and placing the protective screen 80 against a wall after use or when using off-the-shelf X.
The fact that the protective screen 80 is advantageously in one piece, makes it possible to ensure protection on the entire surface of the screen 80 of protection, because there is then neither cut nor hinge, neither hole.
FIG. 8B schematically shows a perspective view of another exemplary remote control station of a catheter drive module in a catheter insertion robot, incorporating a radiation shield, according to an embodiment of the invention. 'invention. The protective screen 80 comprises all or part of the following elements: a glazed area 81, transparent to visible light, an opaque zone 82 to visible light, rollers 803 with brakes 804, several handles 802 arranged so as to allow only one person to roll the protection screen 80 on the ground, preferably hooking means (not shown in Figure 8B because located behind the display screens) of display screens 801, such as screens for duplicating angiography images provided with means for adjusting the height and / or the width, preferably the attachment means (not shown in FIG. 8B) of cables. The protective screen 80 is in one piece but includes two plates 805 and 806 which are not parallel to each other, even if they are monobloc.
The control station 84 comprises all or part of the following elements: rollers 841 with brakes 842, at least one control member 846, preferably a joystick 846, at least one control screen 845, preferably a liquid crystal, preferably touch, at least one other man-machine interface, comprising buttons and / or LED preferably LEDs, preferably accessories 847 hooks, said accessories may be for example a contrast media injection remote control, a control box of an examination table and / or an angiograph arch, a balloon inflator.
On the work table 844 of the control station 84, the control screen 845 reports information on the operation of the insertion robot in response to the control of this insertion robot using the joysticks 846, for example of the joystick type, one for the translation of the insertion robot and the other for the rotation of the insertion robot. This work table 844 rests on a body 843 of the control station 84, and also includes hooks 847 of accessories. Among the accessories that can be hung, there are in particular control boxes of the arch or the table of an angiograph, a remote control of injection of a contrast medium, a balloon inflator located at the end of the catheter and to inflate this balloon.
Of course, the present invention is not limited to the examples and to the embodiment described and shown, but it is capable of numerous variants accessible to those skilled in the art.
Continuation of the description: other objects of the invention
Object 1) Elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising: - an arm (5), - a linear rail (4) non-motorized and carried by the arm (5), - a motorized elongated flexible medical instrument drive module (3) slidable along the linear rail (4).
Object 2) Elongated flexible medical instrument training system according to the object 1, characterized in that: - the elongated flexible motorized medical instrument drive module (3) comprises two parts (14, 15) separable between they: o a motor (14) reusable and non-contact with the linear rail (4), o a carriage (15) disposable sliding on the linear rail (4), this carriage (15) is preferably disposable.
Object 3) Flexible medical instrument training system elongated according to the object 2, characterized in that: - sliding of the carriage (15) disposable on the linear rail (4) performs the translational movement of the medical instrument elongated flexible (1).
Object 4) Elongated flexible medical instrument training system according to any one of the objects 2 to 3, characterized in that: - the disposable carriage (15) comprises a contact surface with the linear rail (4), this contact surface being E-shaped so that the carriage (15) disposable rests on three of the four faces of the linear rail (4).
Object 5) Elongated flexible medical instrument drive system according to any one of the preceding objects, characterized in that: - the linear rail (4) is disposable, and preferably the linear rail (4) is disposable .
Object 6) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that it also comprises: - a sterile barrier (6) consumable passing between the reusable motor (14) and the carriage (15) disposable secured to each other.
Object 7) Elongated flexible medical instrument training system according to the object 6, characterized in that: - this sterile barrier (6) comprises a plate which is perforated so as to let the couplings between the carriage (15) disposable and a reusable motor (14) which is surrounded by a film attached to the edges of the plate.
Object 8) Elongated flexible medical instrument training system according to the object 6, characterized in that: - this sterile barrier (6) includes the disposable carriage (15) which is surrounded by a film attached to the edges of the carriage (15) disposable.
Object 9) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that it also comprises: another sterile (6) consumable barrier encompassing the entire arm (5), but neither the linear rail (4) nor the elongated flexible medical instrument drive module (3).
Object 10) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that: - the stroke of the module (3) motorized along the linear rail (4) is between 60cm and 120cm .
Object 11) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that: the linear rail (4) comprises at least one groove (18) guiding the elongated flexible medical instrument ( 1), preferably the catheter (1) and also the guide (2).
Object 12) Elongated flexible medical instrument training system according to the object 11, characterized in that: -the groove (18) is closed by a cover (19) which opens to the passage of the motorized module (3) and which closes after the passage of the motorized module (3).
Object 13) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that the arm (5) comprises: - a column (11) movable on the one hand in vertical translation and also in horizontal translation, - two V-shaped bars, the tip of the V preferably comprising a ball joint (12) connecting it to the top of the movable column (11), the free ends of the V being preferably fixedly connected to the linear rail (4).
Object 14) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that: the drive system comprises locking elements for locking the assembly constituted by the arm (5); ), by the linear rail (4) and by the module (3) motorized, so that this assembly is movable in one piece relative to the table (7) of operation.
Object 15) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that: - the motorized drive module (3) carries a catheter drive module (1) and a drive module of the guide (2) in translation and in rotation.
Object 16) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that: - the elongated flexible medical motor drive module (3) is driven by a wireless link and / or has as main source of energy, preferably exclusive, one or more electric batteries.
Object 17) Elongated flexible medical instrument training system according to any one of the preceding objects, characterized in that: the elongated flexible medical instrument is a catheter (1) and / or a guide (2).
Object 18) Elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising: - an arm (5), - a linear rail (4) motorized and carried by the arm ( 5), an elongated flexible medical instrument training module (3) sliding along the linear rail (4) under the effect of the sole motorization of the linear rail (4).
Object 19) Elongated flexible medical instrument training system according to the object 18, characterized in that: -the elongated flexible medical instrument training module (3) comprises two parts (14, 15) separable from each other a reusable carriage sliding on the linear rail (4), a disposable support without contact with the linear rail (4), this support being preferably for single use, driving the elongated flexible medical instrument, preferably the catheter ( 1) and preferably also the guide (2).
Object 20) Elongated flexible medical instrument training system according to any one of the objects 18 to 19, characterized in that it also comprises: a consumable sterile skirt (6) passing between the reusable carriage and the disposable support joined together.
Object 21) Flexible medical instrument training system elongated according to the object 20, characterized in that it also comprises: - the sterile consumable barrier, passing between the reusable carriage and the disposable support secured to each other, which also encompasses the whole arm (5).
Object 22) Elongated flexible medical instrument drive system according to any of the objects 18 to 21, characterized in that: the motorized drive module (3) contains a catheter drive module (1) and a drive module of the guide (2) in translation and in rotation.
Object 23) Elongated flexible medical instrument training system according to any one of the objects 18 to 22, characterized in that: - the elongated flexible medical instrument is a catheter (1) and / or a guide (2) .
Object 24) A method for providing a sterile barrier (6) between the consumable and non-consumable portions of an elongated flexible medical instrument drive system of an elongate flexible medical instrument insertion robot, comprising a step of installing a consumable sterile skirt (6) separating a linear rail (4) from at least a portion of an elongated flexible medical instrument training module (3) in this drive system elongated soft medical instrument.
Object 25) Consumable sterile skirt, adapted to separate a linear rail (4) from at least a portion of an elongated flexible medical instrument training module (3) in an elongated flexible medical instrument drive system an elongate flexible medical instrument insertion robot, thereby providing a sterile barrier (6) between the consumable and non-consumable portions of this elongated flexible medical instrument drive system.
Object 26) Elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising a sterile barrier (6) between its consumable and non-consumable parts, comprising: - a linear rail (4) ), - an elongated flexible medical instrument training module (3), - a consumable sterile skirt (6) separating the linear rail (4) from at least a portion of the instrument drive module (3) flexible medical elongated.
Object 27) Elongated flexible medical instrument training system according to the object 26, characterized in that: - the skirt (6) is longitudinally wrinkled on each side of the flexible medical instrument drive module (3) extended, so as to maintain the barrier (6) of sterility for the entire travel in translation of the flexible medical instrument drive module (3) elongated along the linear rail (4).
Object 28) Elongated flexible medical instrument training system according to the object 27, characterized in that: - the wrinkled skirt (6) comprises elastics (31) lateral retaining this skirt (6) wrinkled around the rail linear (4).
Object 29) Consumable sterile skirt according to the object 25, characterized in that: - the skirt (6) is longitudinally wrinkled, on each side of a central portion corresponding to a fixing at the level of the drive module (3). elongated flexible medical instrument, so as to be able to maintain the barrier (6) of sterility for the entire travel in translation of the flexible medical instrument drive module (3) elongated along the linear rail (4), the skirt ( 6) advantageously comprising elastics (31) lateral retaining this skirt (6) wrinkled around the linear rail (4).
Object 30) Elongated flexible medical instrument training system according to the object 26, characterized in that: - the skirt (6) is longitudinally split while having a cover (32) on one side of the slot by the on the other side of the slot so that a sterility channel can be maintained around the linear rail (4).
Object 31) Flexible medical instrument training system elongated according to the object 30, characterized in that: - the slot opens under the effect of a front form (100) of the module (3) spacing flexible medical instrument drive elongated and closes under the effect of a rear shape (101) for closing the elongate flexible medical instrument training module (3).
Object 32) Flexible medical instrument training system elongated according to the object 26, characterized in that: - the skirt (6) is longitudinally split while having slot sides that are joined so as to maintain a gutter sterility around the linear rail (4).
Object 33) Elongated flexible medical instrument training system according to the object 32, characterized in that: - the slot opens under the effect of a front form (100) of spacing of the module (3) flexible medical instrument drive elongated and closes under the effect of a rear shape (101) for closing the elongate flexible medical instrument training module (3).
Object 34) Elongated flexible medical instrument training system according to any one of the objects 32 to 33, characterized in that it also comprises: a pocket surrounding the flexible medical instrument drive module (3) elongate.
Object 35) Elongated flexible medical instrument training system according to the object 26, characterized in that it comprises: a first winder / unwinder (34) secured to a first end of the drive module (3); elongated flexible medical instrument, - a first consumable sterile skirt (6) immobilized on one side with respect to a first end of the linear rail (4), and located on the other side in the first winder / unwinder (34) of so that they can respectively wind up or unwind according to the direction of movement of the flexible medical instrument drive module (3) elongated along the linear rail (4), the first consumable sterile skirt (6) being secured to one side at the first end of the linear rail (4), - a second winder / unwinder (34) secured to a second end of the elongated flexible medical instrument training module (3), - a second pe (6) consumable sterile immobilized on one side with respect to a second end of the linear rail (4), and located on the other side in the second winder / unwinder (34) so as to respectively wind up or unwind while the first consumable skirt (6) unrolls or wraps, the second sterile consumable skirt (6) being secured on one side to the second end of the linear rail (4).
Object 36) Elongated soft medical device driving system according to the object 26, characterized in that: - the sterile skirt (6) consumable has a length which is at least twice the stroke of the module (3) of flexible medical instrument training elongated along the linear rail (4).
Object 37) Flexible medical instrument drive system elongated according to the object 36, characterized in that: - the sterile consumable skirt (6) is smooth over its entire surface.
Object 38) Flexible medical instrument training system elongated according to the object 36 or 37, characterized in that it comprises: - an arterial introducer (8), - a cover (36) located on the side of the introducer arterial (8) arranged to bring the skirt (6) sterile consumable the opposite side with respect to that of the flexible medical instrument drive module (3) elongated with respect to the sliding plane of the linear rail (4).
Object 39) Elongated flexible medical instrument driving system according to the object 26, characterized in that: - the consumable sterile skirt (37) is fixed on the linear rail, - and in that the drive system of Elongated flexible medical instrument comprises another consumable sterile skirt (6) which covers both the linear rail (4) and the elongated flexible medical instrument drive module (3).
Object 40) Flexible medical instrument driving system elongated according to the object 26, characterized in that: - the sterile skirt (6) consumable is arranged around the linear rail (4) so as to be rotated around the linear rail (4), about an axis perpendicular to the longitudinal axis of the linear rail (4), when the elongated flexible medical instrument driving module (3) moves along the linear rail (4).
Object 41) Flexible medical instrument drive system elongated according to the object 40, characterized in that: - the consumable sterile skirt (6) is ballasted to remain around the linear rail (4).
Object 42) Elongated flexible medical instrument training system according to the object 40 or 41, characterized in that it comprises: - flanges for guiding the rotation of the sterile consumable skirt (6) around the linear rail ( 4).
Object 43) Elongated flexible medical instrument training system according to any one of the objects 24 to 42, characterized in that: the elongated flexible medical instrument is a catheter (1) and / or a guide (2) .
Object 44) Elongated flexible medical instrument training system, characterized in that it comprises: - an elongated flexible medical instrument (1), - an elongated flexible medical instrument training module (3), the displacement causes the elongated flexible medical instrument (1) to move, preferably by pushing the elongated flexible medical instrument (1), - an arterial introducer (8), - a guide track (40) of the medical instrument flexible elongated elongated flexible medical instrument training module (3) and the arterial introducer (8).
Object 45) Elongated flexible medical instrument training system according to the object 44, characterized in that: - the guide track (40) is structured so as to open and then preferentially to close at the passage of the module ( 3) elongated soft medical instrument training.
Object 46) Elongated flexible medical instrument drive system according to object 45, characterized in that: - the guide track (40) is a slit tube (43).
Object 47) Elongated flexible medical instrument training system according to the object 45, characterized in that: - the guide track (40) is closed by a zipper (45) or by a zip (45).
Object 48) Elongated flexible medical instrument driving system according to object 44 or 45, characterized in that: - the guide track (40) is a section (400) which is flexible when open and which is rigid when folded and closed.
Object 49) Flexible medical instrument training system elongated according to the object 48, characterized in that the profile comprises: - a bottom (401), - two side members (402) respectively connected to the bottom (401) and articulated relative to this bottom (401), two closure elements (403, 404) respectively situated on the two longitudinal side members (402), able to cooperate together to close the profile (400), the closed cavity of the profile (400). ) being then delimited by the bottom (401), the two longitudinal side members (402) and the two closure elements (403, 404).
Object 50) Elongated flexible medical instrument driving system according to the object 49, characterized in that: - the dimensions of the longitudinal members (402) and the bottom (401), in a cross section of the profile (400), are determined so that: - on the one hand the profile (400) is self-supporting when the closing elements (403, 404) are closed, - on the other hand the profile (400) is not self-supporting, when the closing elements ( 403, 404) are open.
Object 51) Elongated flexible medical instrument drive system according to the object 49 or 50, characterized in that: - the closure elements (403, 404) mate by clipping into one another.
Object 52) An elongated flexible medical instrument drive system according to any one of the objects 49 to 51, characterized in that: - the joints are material thickness fades (405).
Object 53) Elongated flexible medical instrument training system according to the object 52, characterized in that: - the material thickness weakenings (405) are indentations each with bevelled edges (406) parallel.
Object 54) Elongated flexible medical instrument drive system according to the object 53, characterized in that: - each notch has an enlarged bottom (407) with respect to the width between the bevelled edges (406).
Object 55) Elongated flexible medical instrument drive system according to the object 44, characterized in that: - the guide track (40) has the shape of a cable chain 41) having a longitudinal opening which is of width smaller than the diameter of the elongated flexible medical instrument (1) and which is flexible but asymmetrical so as to allow the elongated flexible medical instrument (1) to enter more easily than exit.
Object 56) Elongated flexible medical instrument driving system according to the object 44, characterized in that: - the guide track (40) is in the form of a spiral (46) wrapping around the instrument Elongated flexible medical device (1), this spiral (46) being rotatable around the elongated flexible medical instrument (1).
Object 57) Elongated flexible medical instrument training system according to the object 44, characterized in that: - the guide track (40) comprises two parts (49) which are fixed at one end to the module (3) of elongated flexible medical instrument training, which are respectively fixed by the other end inside two reels (48), which form a single band outside these two reels (48) in which they are respectively wound as sliding of the flexible medical instrument training module (3) elongated to the arterial introducer (8).
Object 58) Elongated flexible medical instrument drive system according to the object 44, characterized in that: - the guide track (40) comprises two flexible crenated rectangular portions (410) when separated one from the other. the other constituting a rigid pipe of rectangular section when they are nested one inside the other.
Object 59) Elongated flexible medical instrument driving system according to the object 44, characterized in that: - the guide track (40) is bellows-shaped (412).
Object 60) Elongated flexible medical instrument training system according to the object 44, characterized in that the guide track comprises: - an open and rigid guide channel in the hollow of which is located the elongated flexible medical instrument ( 1), - a flexible cover (414) which is fixed at one end to the elongated flexible medical instrument drive module (3) and which is secured by the other end to a winder (48) wherein it is wound as the flexible elongated medical instrument drive module (3) is slid to the arterial introducer (8).
Object 61) Elongated flexible medical instrument training system according to any one of the objects 44 to 60, characterized in that: - the elongated flexible medical instrument is a catheter (1) and / or a guide (2) .
Object 62) Elongated flexible medical instrument drive system of an elongated flexible medical instrument insertion robot, comprising: - an articulated arm (5) comprising at least three articulated and robotized segments (50) which is adapted to describe a linear trajectory in space at its distal end, - an elongated flexible medical instrument training module (3) secured to this distal end.
Object 63) Elongated soft medical instrument driving system according to object 62, characterized in that: - the orientation, in space, of the elongated flexible medical instrument training module (3) being maintained constant during its displacement along said linear path.
Object 64) Elongated flexible medical instrument driving system according to the object 62, characterized in that: - this linear trajectory in the space remains in a horizontal plane, that is to say in a plane parallel to the plan of the examination table (7).
Object 65) Elongated flexible medical instrument training system according to any one of the objects 62 to 64, characterized in that: - this arm (5) comprises at least four segments (50) hinged together, preferably only four segments (50) hinged together.
Object 66) Elongated flexible medical instrument training system according to any one of the objects 62 to 65, characterized in that it also comprises: an adjustment rail (10) carrying the proximal end of this arm ( 5), - a locking device of this proximal end of the arm (5) on the adjusting rail (10) during the linear displacement of this distal end.
Object 67) Elongated flexible medical instrument training system according to the object 66, characterized in that: the adjusting rail (10) rests on a table (7) of examination, advantageously fixed on this table (7). ) of examination.
Object 68) Elongated flexible medical instrument training system according to any one of the objects 62 to 65, characterized in that: the proximal end of this arm (5) rests on an examination table (7) , articulated by a rotational connection relative to this examination table (7), preferably articulated only by this rotational connection relative to this table (7) examination.
Object 69) Elongated flexible medical instrument training system according to any one of the objects 62 to 65, characterized in that it also comprises: an adjusting rail (10) carrying a bracket (52) not articulated to which is secured to the proximal end of this arm (5), - a locking device of this bracket (52) on the adjusting rail (10) during the linear displacement of the distal end.
Object 70) Flexible medical instrument training system elongated according to the object 69, characterized in that: the adjustment rail (10) rests on a table (7) of examination, advantageously fixed on this table (7). ) of examination.
Object 71) Elongated flexible medical instrument training system according to any one of the objects 62 to 65, characterized in that it also comprises: a non-articulated stem resting on the ground (102) to which is secured the proximal end of this arm (5), - a device for controlling the movement of an operating table (7) during the linear displacement of this distal end.
Object 72) Elongated flexible medical instrument training system according to the object 71, characterized in that: - the stem rests (53) on the ground (102).
Object 73) Elongated flexible medical instrument training system according to object 71 or 72, characterized in that: - the stem is higher than the examination table (7) associated with the instrument drive system flexible medical elongated.
Object 74) Elongated flexible medical instrument training system according to any one of the objects 62 to 65, characterized in that it also comprises: an articulated control arm (5) carrying the proximal end of this arm (5) robotic, - a locking device of the adjusting arm (54) articulated during the linear movement of the distal end.
Object 75) Elongated flexible medical instrument training system according to the object 74, characterized in that: - the articulated control arm (54) rests on a table (7) of examination, advantageously fixed on this table ( 7) Examination.
Object 76) Elongated flexible medical instrument training system according to the object 74 or 75, characterized in that: - the articulated control arm (54) comprises at least three segments (50) hinged together.
Object 77) Elongated flexible medical instrument training system according to any one of the objects 62 to 65, characterized in that it also comprises: a column (11) to which is secured the proximal end of this arm (5) articulated robotic, - and in that all segments (50) of the robotic articulated arm (5) unfold only in a horizontal plane (X, Y).
Object 78) Flexible medical instrument drive system elongated according to the object 77, characterized in that: - the column (11) is non-articulated.
Object 79) Elongated flexible medical instrument driving system according to the object 77 or 78, characterized in that it also comprises: - an adjusting rail (10) on which the column (11) rests, - a device locking this column (11) on the adjusting rail (10) during the linear displacement of this distal end.
Object 80) Elongated flexible medical instrument driving system according to the object 79, characterized in that: - the adjusting rail (10) rests on a table (7) of examination.
Object 81) Elongated flexible medical instrument training system according to any of the objects 62 to 80, characterized in that: - the elongated flexible medical instrument is a catheter (1) and / or a guide (2) .
Object 82) Connection between arterial introducer (8) and catheter guide tube (61) of an elongated flexible medical instrument insertion robot, - comprising two parts (62) interconnected by at least one first attachment ( 63), now the arterial introducer (8) in the extension of the guide tube (61) for moving the elongated flexible medical instrument (1) from the guide tube (61) to the arterial introducer (8) by pushing the elongate flexible medical instrument (1), - the tensile strength, along the axis of the elongate flexible medical instrument (1) passing through the connector (60), of the first fastener (63), before releasing the two portions (62) of the connector (60) from one another is less than the resistance of the arterial introducer (8) introduced into the patient (9) before it comes out.
Object 83) Connection between arterial introducer and elongated flexible medical instrument guide tube of an elongated flexible medical instrument insertion robot, - comprising four portions (62) interconnected by at least one first attachment (63) ), now the arterial introducer (8) in the extension of the guide tube (61) for passing the elongated flexible medical instrument (1) from the guide tube (61) to the arterial introducer (8) by pushing the elongate flexible medical instrument (1), said first fastener (63) connecting two of the portions (62) located on one side of a plane transverse to the other two portions (62) located on the other side of said transverse plane; - comprising at least a second fastener (64), cooperating with the first fastener (63) for immobilizing, between them, the four parts (62) of the connector (60), the arterial introducer (8) and the guide tube ( 61), this second fastener (64) connecting two of the parts (62) located on one side of a longitudinal plane to the other two portions (62) on the other side of said longitudinal plane; - tensile strength along the axis of the flexible medical instrument lengthened (1) passing through the connector (60) of the first fastener (63) prior to release is less than this resistance of the second fastener (64) prior to release.
Object 84) Connection according to the object 83, characterized in that: - the second fastener (64) cooperates with a flexible hinge (69) which facilitates the opening and closing of the second fastener (64).
Object 85) Connection according to any of the objects 82 to 84, characterized in that: - the first fastener (63) comprises at least one central clip, and preferably several longitudinal clips, - the second fastener (64) comprises at least one minus one side clip, and preferably several side clips.
Object 86) Connection according to any of the objects 82 to 85, characterized in that: the second fastener (64) secures the guide tube (61) to the coupling (60) via a sleeve (65). ) surrounding the guide tube (61), which sleeve (65) can be held in place in the fitting (60) by the second fastener (64) at several positions along the axis of this sleeve (65).
Object 87) Connection according to the object 86, characterized in that: - this sleeve (65) has splines (66) along its axis.
Object 88) Connection according to the object 87, characterized in that: - these grooves (66) are arranged periodically along the axis of the sleeve (65).
Object 89) Connection according to the object 87 or 88, characterized in that: the number of grooves (66) is between 5 and 15, advantageously 10, the dimension of the hollow as the bump of each groove (66) being between 0.5 mm and 2 mm, advantageously being 1 mm
Object 90) Connection according to any one of the objects 86 to 89, characterized in that: - this sleeve (65) is permanently fixed on the guide tube (61) which it surrounds.
Object 91) Connection according to any of the objects 82 to 90, characterized in that: -the connector (60) comprises a lateral opening (67) allowing the introduction into the connection (60) of another pipe (87) from the arterial introducer (8).
Object 92) Connection system, comprising: - a connector (60) according to any of the objects 82 to 91, - an arterial introducer (8), -a guide tube (61) of the elongated flexible medical instrument ( 1) an elongated flexible medical instrument insertion robot.
Object 93) Connection system according to the object 92, characterized in that it comprises: - a catheter (1) and a guide (2) coaxial.
Object 94) Connecting system according to any of the objects 82 to 93, characterized in that: - the elongated flexible medical instrument is a catheter (1) and / or a guide (2).
Object 95) Elongated flexible medical instrument drive module of an elongate flexible medical instrument insertion robot, comprising: at least three rotatable rollers (71, 73), and preferably only three rollers (71, 73) rotatable and movable relative to each other so as to be closer to each other so as to form a baffle (70) therebetween during passage of the elongate flexible medical instrument (1).
Object 96) Elongated flexible medical instrument drive module according to the object 95, characterized in that: - at least one of the three rotary rollers is a driving motor roller, and preferably only one of the three rollers is a drive motor roller.
Object 97) Elongated flexible medical instrument drive module according to the object 95 or 96, characterized in that: - the axes of rotation of the rotatable rollers (71, 73) are parallel to each other and the rollers (71, 73 ) are circular in a plane perpendicular to their axes of rotation.
Object 98) Elongated flexible medical instrument drive module according to the object 97, characterized in that: - the peripheries (74) of two rollers (73) are tangent to the periphery (72) of a third roller ( 71).
Object 99) Flexible medical instrument drive module elongated according to the object 98, characterized in that: - the third roller (71) has a greater diameter than those of the other two rollers (73).
Object 100) Flexible medical instrument training module elongated according to the object 99, characterized in that: -the third roller (71) is a roller (71) for driving the elongated flexible medical instrument (1) , while the other two rollers (73) are pressure rollers (73) of the elongated flexible medical instrument (1) against the third drive roller (71).
Object 101) Elongated flexible medical instrument drive module according to any of the objects 98 to 100, characterized in that: - these two other rollers (73) have the same diameter between them.
Object 102) Elongated flexible medical instrument training module according to any one of the objects 97 to 101, characterized in that: - in a plane perpendicular to the axes of rotation of the rollers (71, 73), the angle whose apex is the center of the third roller (71) and which is formed by the two straight lines respectively connecting the centers of the two other rollers (73) to the center of the third roller (71), is between 60 degrees and 120 degrees, and is advantageously about 90 degrees.
Object 103) Elongated flexible medical instrument training module according to any one of the objects 95 to 102, characterized in that: at least the third roller (71) and preferably also the two other rollers (73), has a concave slice (75) of centric guide of the elongated flexible medical instrument (1).
Object 104) Elongated flexible medical instrument training module according to any of the objects 95 to 103, characterized in that: - the concavity of this slice (75) is between one quarter and three quarters of the diameter of the elongated flexible medical instrument (1), advantageously being half the diameter of the elongated flexible medical instrument (1).
Purpose 105) Elongated flexible medical instrument drive system, comprising: - an elongated flexible flexible medical instrument insertion robot elongated medical instrument training module (3) according to any one of the objects 104, - an elongated flexible medical instrument (1) passing through the baffle (70) formed by the rollers (71, 73).
Object 106) Elongated flexible medical instrument training system according to any of the objects 95 to 105, characterized in that: - the elongated flexible medical instrument is a catheter (1) and / or a guide (2) .
Object 107) Remote control cockpit of an elongated flexible medical instrument insertion robot comprising: a control station (84) of said elongated flexible medical instrument insertion robot, without an integrated X-ray shield an X-ray protective screen (80) independent of said control station (84).
Object 108) Cockpit according to the object 107, characterized in that: - said protective screen (80) is movable on the ground, preferably said protective screen (80) rolls on the ground.
Object 109) Cockpit according to the object 107 or 108, characterized in that: - said control station (84) is movable on the ground, preferably said control station (84) rolls on the ground.
Object 110) Cockpit according to any of the objects 107 to 109, characterized in that: - said protective screen (80) is transparent to visible light on at least a portion of its surface, preferably over its entire width, and over more than half of its height.
Object 111) Cockpit according to any one of the objects 107 to 110, characterized in that: - said protective screen (80) is in one piece.
Object 112) Cockpit according to any one of the objects 107 to 111, characterized in that: - said protective screen (80) comprises at least two planes not parallel to each other.
Object 113) Cockpit according to any one of the objects 107 to 112, characterized in that said protective screen (80) comprises all or part of the following elements: - a glazed area (81), transparent to visible light, - a opaque zone (82) in visible light, - wheels (803) with brakes (804), - a plurality of handles (802) arranged to allow one person to roll the protection screen (80) on the floor, - preferably means for attaching viewing screens, such as for example angiography image duplication screens provided with height and / or width adjustment means, - preferably hooking means of cables.
Object 114) Cockpit according to any one of the objects 107 to 113, characterized in that said control station (84) comprises all or part of the following elements: - wheels (841) with brakes (842), - at least one control member (846), preferably a joystick, - at least one control screen (845), preferably liquid crystal, preferably tactile, - at least one other man-machine interface, comprising buttons and / or indicator lights preferably light-emitting diodes, - preferably hooks (847) of accessories, said accessories being for example a remote control of injection of contrast medium, a control box of an examination table and / or of an arch of angiograph, a balloon inflator.
Object 115) Elongated flexible medical instrument drive system according to any one of the objects 107 to 114, characterized in that: the elongated flexible medical instrument is a catheter (1) and / or a guide (2) .

权利要求:
Claims (9)
[1" id="c-fr-0001]
1) Remote control cockpit of an elongated flexible medical instrument insertion robot comprising: - a control station (84) of said elongated flexible medical instrument insertion robot, without an integrated X-ray shielding screen an X-ray protective screen (80) independent of said control station (84).
[0002]
2) A cockpit according to claim 1, characterized in that: - said protective screen (80) is movable on the ground, preferably said protective screen (80) rolls on the ground.
[0003]
3) A cockpit according to claim 1 or 2, characterized in that - said control station (84) is movable on the ground, preferably said control station (84) rolls on the ground.
[0004]
4) Cockpit according to any one of claims 1 to 3, characterized in that: - said protective screen (80) is transparent to visible light on at least a portion of its surface, preferably over its entire width, and over more than half of its height.
[0005]
5) Cockpit according to any one of claims 1 to 4, characterized in that: - said protective screen (80) is in one piece.
[0006]
6) Cockpit according to any one of claims 1 to 5, characterized in that: - said protective screen (80) comprises at least two non-parallel planes between them.
[0007]
7) Cockpit according to any one of claims 1 to 6, characterized in that said protective screen (80) comprises all or part of the following elements: - a glazed area (81), transparent to visible light, - a zone opaque (82) to visible light, - rollers (803) with brakes (804), - a plurality of handles (802) arranged to allow one person to roll the shield (80) on the floor - Preferably means for attaching display screens, such as angiography image duplication screens provided with height and / or width adjustment means, - preferably means for attaching cable.
[0008]
8) Cockpit according to any one of claims 1 to 7, characterized in that said control station (84) comprises all or part of the following elements: - wheels (841) with brakes (842), - at least one member control device (846), preferably a joystick, - at least one control screen (845), preferably a liquid crystal display, preferably tactile, - at least one other man-machine interface, comprising buttons and / or indicator lights preferably light-emitting diodes, - preferably hooks (847) of accessories, said accessories can be for example a remote control of injection of contrast medium, a control box of an examination table and / or a angiograph arch, a balloon inflator.
[0009]
9) Elongated flexible medical instrument training system comprising a cockpit according to any one of claims 1 to 8, characterized in that: - the elongated flexible medical instrument is a catheter (1) and / or a guide ( 2).

类似技术:

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同族专利:

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公开号 | 公开日

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FR3048888A1|2017-09-22|

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FR3048889B1|2022-01-07|

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FR3048889A1|2017-09-22|

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US20200297434A1|2020-09-24|

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BR112018068536A2|2019-01-29|

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FR3048891B1|2018-03-23|

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EP3429502A1|2019-01-23|

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FR3048890A1|2017-09-22|

---

CN109152616A|2019-01-04|

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KR20180138202A|2018-12-28|

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WO2017158263A1|2017-09-21|

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JP2019512319A|2019-05-16|

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法律状态:
2017-01-26| PLFP| Fee payment|Year of fee payment: 2 |

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2017-09-22| PLSC| Publication of the preliminary search report|Effective date: 20170922 |

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2018-01-29| PLFP| Fee payment|Year of fee payment: 3 |

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2019-01-30| PLFP| Fee payment|Year of fee payment: 4 |

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2020-01-29| PLFP| Fee payment|Year of fee payment: 5 |

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2021-02-24| PLFP| Fee payment|Year of fee payment: 6 |

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2022-02-23| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1652304A|FR3048888A1|2016-03-18|2016-03-18|INSULATED MEDICAL INSTRUMENT ROBOT WITH LONG-SIDED MEDICAL INSTRUMENT AND ASSOCIATED ACCESSORIES|

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FR1652304|2016-03-18|

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FR1657678A|FR3048891B1|2016-03-18|2016-08-10|INSULATED MEDICAL INSTRUMENT ROBOT WITH LONG-SIDED MEDICAL INSTRUMENT AND ASSOCIATED ACCESSORIES|FR1657678A| FR3048891B1|2016-03-18|2016-08-10|INSULATED MEDICAL INSTRUMENT ROBOT WITH LONG-SIDED MEDICAL INSTRUMENT AND ASSOCIATED ACCESSORIES|