FR3019983A1 - EXOCENTRIC SURGICAL DEVICE - Google Patents

Abstract

Surgical device (100) comprising at least one hoop (1) movable in rotation about an axis (R) and adjustable in position around this axis and at least one instrument holder (30) movable along said at least one hoop (1) and adjustable in position thereon.

Description

The present invention relates to devices used in robotic surgery. Robotic surgery still only concerns a small range of operations, for example interventions via the peritoneum, or operations of prostate cancer. Other surgeries do not use or very little robot. The need to use more widely the surgical robots faces several problems. The main brake is that the morphology of the robots generally used is not adapted to work in microsurgery. The robotic equipment currently used in surgery is bulky, heavy, expensive, complicated to install and maintain. Their use also requires learning from the surgeon and his team. Conventionally, robotic surgery uses an opening in the body of the patient through which the various instruments pass. One of the needs is to make the surgery the least invasive possible to limit the trauma due to the operation and to shorten the healing time. In the robots currently used in surgery, it is particularly difficult to focus all the ins ents on the same point and it is not uncommon that during the operation the focus point goes wrong and the surgeon loses weight. time to find it again and adjust the positioning of the different instruments. In neurology, it is known to use a Leksell device attached to the head of a patient. For example, the application WO 2009/047494 describes a guide for a neurosurgical instrument comprising an arched support attached to a base positioned on the skull of a patient. Such igues stereo systems are also known in radiotherapy to accurately position a non-invasive radio-surgical instrument to the area to be treated. These devices are not suitable for the use of several instruments focused on the same area. There is a need to make robotic surgery equipment smaller, easier to use and less expensive and suitable for precision surgical procedures. There is still no interest in facilitating and increasing the speed of adjustment in position of the various instruments during a robotic surgical procedure. The invention aims to meet all or part of these needs.

According to a first aspect, the invention relates to a surgical device comprising at least one hoop movable in rotation about an axis and adjustable in position about this axis and at least one movable carrier along said at least one hoop and adjustable in position on it.

The device may comprise a single arch or an assembly of at least two interconnected arcs, in particular traversed by a pivot axis corresponding to the axis of rotation. The instrument holder can be removable. When using the device for surgery, the instrument holders may directly carry a surgical insert. In the context of the invention, the term "instrument" must be understood in a broad sense, which may mean an element such as a surgical instrument, a camera, a lighting system or a trocar to introduce such an element. For example, at least one instrument holder carries a trocar through which surgical inserts or a camera are introduced into the patient body, in particular all the instrument holders carry a trocar. The invention allows the positioning and the holding in position of the instruments throughout an operation. Thanks to the invention, all the ins ents can converge towards a central point of the operative field targeted by the surgeon. At least one instrument holder may comprise means for actuating in the position of the pins that it carries, in particular for actuation in height relative to the point of intervention targeted by the surgeon. The actuation height can correspond to a translational movement along an axis of the instrument holder.

Each instrument holder may thus comprise means for positioning the insert axially along a proper axis. The axes of axial displacement of the instrument holders can be cut at a fixed point relative to the or the arches, the axes pivoting around said point as a function of the movements of the arches and inser-ents.

In the context of the present application, such a device is described as "exocentric".

An exocentric device is p. It is particularly advantageous for the surgeon during an operation not to permanently lose the focus of the instruments. If the surgeon wishes to leave the central focusing point in order to work momentarily at his periphery, the invention may allow him, as explained later, to then easily return to the initial position. Thus, thanks to the invention, all instruments can easily converge to a central point corresponding to the work point targeted by the surgeon. Furthermore, while other microsurgical devices favor overall and relatively wide access to the operating site to allow the passage of different instruments, the invention favors several smaller incisions so less traumatic, faster to. heal and less prone to infections. Alternative embodiments may have various dimensions. The invention particularly facilitates interventions at the level of the lower or upper limbs, for example an operation of the hand or the arm.

Larger devices are suitable for head operations and larger dimensions of a device according to the invention may allow interventions on other parts of the body, for example the thorax. Device frame The device may comprise a frame integral with the arch or hoops.

This is, respectively these are for example mobile (s) relative to said frame, p. spoon in translation along an axis. The frame comprises for example two parallel rails carried by a frame and along which move or the arches. The frame can be configured to be able to rest, in particular to be firmly fixed, on an operating table so as to choose the orientation of the axis of rotation of the hoops, in horizontal or vertical peculiar. The frame can be configured to be able to rest and be fixed on an operating table so that the axis of movement of the bow or hoops is oriented horizontally or vertically. The frame may comprise two feet, in particular of elongated shape, connected by two parallel rails. The elongated form of the legs advantageously allows greater angular variation s s the positioning of the hoops.

The feet can be configured to provide several possible positions of the device on the operating table. The device may for example rest on long sides of the feet, or small sides or on an outer face of one of the feet. The chassis may further comprise at least one movable fixing means along the second axis, in particular perpendicular to the axis of displacement of the arch or hoops, the fastening means being configured to receive, removably or not, a shelf arranged to carry a support for the p. e to operate from a patient. The fixing means of the shelf comprises for example two movable slides along elongated chassis rails along the second axis.

Displacement and Focusing of Surgical Instruments An instrument holder is configured to be mounted on an arch, giving the corresponding instruments several degrees of freedom. An instrument holder may comprise first positioning means on a hoop. An instrument holder can be fixed in a particular position on the hoop by snapping, clamping around the hoop ... this list being non-limiting. The first positioning means used may be of a type known to those skilled in the art and comprise, for example, a jaw to be clamped on the hoop or a set screw. At least one hoop pivots about the axis of rotation, according to a first rotational movement.

A hoop, or all the hoops, may have a curved shape included in a plane. The movement of each instrument carrier can be included in a plane defined by the corresponding arch. Preferably, each carrier is movable along the hoop which supports it in a second rotational movement. At least one of the arches has for example the shape of an arc of a circle, in particular of a semicircle. In a variant, a bow forms a complete ring. Preferably, all the arches have the shape of an arc of a circle, in particular of a semicircle. The hoop may be configured to facilitate movement of the implement holder along the hoop and to prevent the implement holder from pivoting about the hoop. The arch section, or all of the arches, is for example flattened, having in particular a rectangular or square shape. In a variant a hoop is composed of several tubes, for example two circular tubes of different identical section, forming a geometric structure similar to rails. An instrument holder may comprise second positioning means configured to adjust the position of the instrument relative to the corresponding instrument holder. The second positioning means may comprise a clamping system by jaws or pressure screw allows an axial adjustment of the trocar. The translational movement of the instrument is for example parallel to the plane of movement of the instrument holder on the hoop.

Alternatively or additionally, the axis of the translational movement of the instrument holder may pass through the center of the rotational movement of the insert holder on the corresponding arch. In an alternative or complementary embodiment, the instrument may have a rotational movement relative to the instrument holder which carries it, which adds an additional axis of movement. The instrument can thus have the possibility of rotation on itself. The surgical device according to the invention can thus offer at least three degrees of freedom for the positioning of surgical instruments without moving the central point of work. In a particular embodiment, a slight displacement of the instrument holder makes it possible to leave the central focusing point in order to work in its periphery. The instrument holder can for example offer two degrees of freedom additional trocar or the instrument that carries. The instrument holder can thus allow a slight rotation and / or translation of the trocar or the instrument. The holder can thus define two additional axes of rotation. When the set of arches is movable relative to the operated portion of the patient's body as previously described, the surgical device may provide one or two additional degrees of freedom for the relative positioning of the arches and the operative site. Movement The displacement of the various elements of the device in order to adjust their respective relative positions as well as their position relative to the operating field can be performed manually.

In particular to move and hold in position at least one of the arches and / or the instrument holder with respect to a hoop, the device may comprise an actuating system. The latter can control movements trocar or instrument housed in an instrument holder.

In a variant, the actuation system controls the movements of a tablet for supporting a limb to be operated. The actuating system may comprise a mechanical or electromechanical actuator allowing displacement with a submillimetric adjustment of the positions of the various elements of the device (arches, instrument holders and / or inserts). The actuating system can be motorized and include for example stepper motors to allow to perform, at least in part, the rotations and translations necessary for the movements of the instruments. The actuation system may comprise geared motors. The hoops can be notched thus forming a rack on which can move an instrument holder equipped with a gear motorized particular. The actuating system can be configured to move and hold in position all the instruments carried by an instrument holder and each instrument holder on the corresponding arch. In a variant, the actuation system controls the movements of the arches relative to one another as well as those of the set of arches relative to the limb to be operated. Preferably the actuating system is configured to control the movements relative to the frame of a possible tablet for supporting a member to operate. The actuation system can be remotely controlled by a remote control system, in particular via a wireless link.

The device may include a security system, including a brake system, which locks at least one degree of freedom, or all. By a security system means any means to prevent involuntary and / or uncontrolled relative movement of the various elements of the device.

The security system operates for example by friction of moving components between them. In a variant, the safety system simply comprises servocontrolling the motors for which a holding current is programmed. The device can be graduated in order to facilitate the positioning of each component. In particular, the device may have a scale of graduation for each degree of freedom. For example, a hoop or even each hoop has a graduated scale and / or is notched. Each holder can be graduated and / or notched. The frame may comprise a scale graduated according to each axis of movement of the arch or bars attachment means. This graduation 15 may be visual and / or electronic thanks to an encoder known to those skilled in the art, for example an encoder wheel or an electronic caliper. Hoops A hoist can carry several carriers simultaneously. The number of arches and the number of instrument holders are not limited, only the size of the instrument holders and surgical instruments attached to the device can be a restriction because, depending on the needs, the scientist must be able to modify the position. relating to instruments in the course of intervention. The device comprises for example between one and six arches, including two, three or four arches. The hoop is for example fixed to at least one hub movable about the axis of rotation, or to two hubs diametrically opposite with respect to the hoop. Each arch of the device may comprise two ends, at least one or even each is for example terminated by the movable hub about the axis of rotation of the hoops. In a variant, the device comprises a single hoop, in particular forming a complete circle, for example integral with a hub movable about the axis of rotation.

At least one arch, or even each arch, may have a shape included in a plane, that is to say that the corresponding instrument holder moves in a plane. The plane of movement of the instrument holder may be parallel to the axis of movement of the instrument inside the instrument holder and / or through the axis of rotation of the arch.

In a first embodiment, the plane of movement of the instrument holder is parallel to the axis of rotation of the corresponding arch from which it is distant from a non-zero distance. In particular the plane of movement of the instrument holder may be tangent to the hub, the distance between the axis of rotation of the hoop and said plane being equal to the hub radius. The axis of movement of the instrument on the instrument holder is then for example parallel to this plane and distant from the plane by a distance equal to the radius of the hub, the instrument and the center of the hub being on the same side of the plan of movement of the inset holder. In a second variant embodiment the plane of movement of the instrument holder contains the axis of rotation of the arches. The axis of movement of the instrument on the instrument holder is then inclined for example with respect to this plane and, preferably, pivots around a fixed central point of the device when the instrument holder is moved along the arch supporting it. The arches may be integral, being in particular interconnected at their hub. The hubs of the same end of the hoops are for example traversed by a pin-shaped axis, for example a central pivot. The hubs may have shapes that correspond or not. At least one hoop may be totally free around the axis of rotation, at least when it bears no inserts, that is to say it can rotate 360 ° on itself, independant of the orientation of the other arches. The size of one or more instruments may interfere with such rotation in a particular configuration. Camera Holder and Camera Holder The insert holder may carry, directly or indirectly, a camera and / or a flesh spacer system to clear a subcutaneous operative space.

When an instrument holder carries a spacer system, the surgeon sets the orientation of the axis of the instrument holder and the height of the spacer system for the subcutaneous space cleared is sufficient. In a variant, the surgical device comprises a camera attached directly to a hoop and not to an instrument holder. The surgeon adjusts the position of the camera relative to the operating site by fixing the position of the camera on the corresponding arch. In a preferred embodiment, the camera and the instruments are carried by an arch. More generally, the surgeon adjusts the position of the instrument relative to the operating site by fixing the position of the instrument holder on the corresponding arch and that of the ins ent relative to the instrument holder. Each instrument holder can be removable. The surgical device may comprise a laser pointer to facilitate the adjustment in position of the various components of the device relative to the part to be operated on by the patient. The practitioner or his assistant can fix one or more markers, including radiopaque, on the member to operate. Preferably the markers are at least three in number. In a variant it uses alternatively or complementary morphological landmarks. At least one image is then made by medical imaging, p. scanner-type or / and I 'in order to determine the point of focus of the surgery then and to choose the penetration vectors of the instruments. The device can be arranged to calculate, from this selected point, by an algorithm the position of each component of the device (hoop, instrument holder, support) in order to orient the instruments towards the point to be treated. The surgeon adjusts the device in position and positions the limb on the support. By locating the radio-opaque points of the limb and the laser pointer, the surgeon then makes the various adjustments manually. In one variant, the Cartesian coordinates obtained by the medical images are translated into polar coordinates according to a protocol of the device and the settings are then done automatically.

Each axis of the instrument holder is positioned to aim at a corresponding area to incise the trocar, the instrument or the camera into the area to be operated. According to yet another aspect, the subject of the invention is a method for calculating and / or adjusting the position of surgical instruments, in particular during a laparoscopic, diagnostic or surgical procedure, for example lower or upper limbs. .., using a surgical device according to the invention. During operation, it is often necessary, in order to constantly obtain a good position, both surgical instruments, lighting and the camera, to adjust the respective positions of the components of the device several times. The method using a device as described allows a faster and more reliable adjustment. The invention will be better understood on reading the detailed description that follows, examples of non-limiting implementation thereof, and on examining the appended drawing, in which: FIGS. 1 and 2 illustrate in perspective and side example embodiment of surgical device according to the invention, - Figures 3 to 5 show various orientations and positioning of surgical devices according to the invention - Figures 6 and 7 illustrate in isolation and perspective variants FIG. 8 illustrates a surgical device according to the invention during an operation of the wrist, FIG. 9 is a perspective view of another embodiment of a surgical device according to the invention, and FIGS. 10A. at 10E illustrate in section different arches. FIG. 1 represents a device 100 according to the invention comprising together 10 three arches 1, each terminated at its two ends by a hub 2 movable about the same axis of rotation R. The arches 1 are integral at the hubs 2 which are in the illustrated example traversed by a central pivot 20.

At least one hoop 1 is completely free to rotate about the axis R, that is to say that it can rotate 360 °, in the example shown, the hoop 1 carrying the trocar 150 camera 140 .

In the illustrated example, each arch 1 has the shape of a semicircle and defines a plane PA tangent to the hubs 2 and remote from the axis R by a distance D. Each arch 1 carries a configured instrument holder 30 to move in the plane PA by a circular motion of an angle 3 measured from the axis R along the corresponding arch 1. The instrument holders of the illustrated device thus carry a trocar 150 for the passage of a surgical instrument 135 or a camera 140. In a variant not shown, one of the instrument holders 30 carries a system of separation of the flesh. Each holder defines a z-axis of movement of the trocar 150, the Z axes intersect at a point O. For each instrument holder, the Z axis is parallel to PA, located at a distance d and the same side of PA that the hub 2 of the arch 1 corresponding. The dis. these D and d compensate for the point O remains fixed relative to the assembly 10 regardless of the position of the arches 1 and the instrument holders 30 on the arches. The illustrated device 15 is exocentric within the meaning of the invention. In another variant, not shown, of an exocentric device, the PA planes of the different arches are intersecting in the axis of rotation R and the Z axes form a non-zero angle by compared to the PA plan. The device 100 further comprises a motorized actuating system 80 comprising geared motors 85, no. stepping or direct current, fixed at the hubs 2 to control the displacement of the assembly 10 fixed on the sliders 15 along the axis X and the rotation about the axis R of each arch 1, respectively on each instrument carrier 30 to control the movement of the instrument holder along the hoop 1 which carries it and the movements of the instrument inside the instrument holder 30. The gearmotors 85 are controlled remotely via a wired or wireless connection by an actuation system not shown. The actuation system also includes a brake system not shown to secure the position of the assembly 10, arches 1, instrument holders 30 and trocars. During an operation, the surgeon can begin by predefining, depending on the operation concerned, the orientation of the arches 1 by rotation of angle around the axis R, each arch 1 pivoting about the axis R according to the double arrow A illustrated in FIG. 2. Thereafter, the practitioner moves the instrument holders 30 along the arches 1 in a circular manner along the double arrow B of FIG. 1. The instrument holders are thus pre-positioned to limit the overall bulk when the instruments and the camera are set up so that subsequent movements of the arches or instrument holders are possible during operation without the instrument holders or instruments interfering with each other . The angles a and 0 can be determined by an algorithm and correspons rotations. The presets of the angles a and 13 are, for example, calculated by the algorithm using images of the limb using medical imagery. The practitioner uses, for example, one or more radiopaque markers positioned on the limb to be operated or morphological markers. The surgeon also adjusts the height of the trocars, instruments or camera 15 in each instrument holder 30 along the Z axis by a rectilinear movement along the double arrow C of FIG. 2. The movements according to A, B and C make it possible to moving each instrument 135 without moving the central focusing point O. All degrees of freedom are lockable by a brake system, for example a hydraulic, pneumatic or electromechanical brake The pre-positioned device rests on the operating table by means of intermediate of two elongated and parallel feet of a frame 50. In the illustrated example, the surgical device optionally comprises a tablet 60 for receiving the member to operate, for example a hand. The tablet 60 25 is in particular provided with a support 62. Depending on the type of surgical procedure, the support 62, or even the tablet 60, may be necessary or not. The surgeon also sets the positioning of the set 10 of the arches 1 along the X axis by moving the sliders 15 on the slides 16 and the positioning along the Y axis of a shelf 60 removably attached to the frame 50 with the movable slides 65 along the slides 66.

In the nonlimiting example illustrated, the fixing slides 15 and 65 slide on rails 16 and 66 in the form of bars. In ur, not shown example the slides move along rails. The device 100 illustrated in FIG. 3 comprises only two arches 1 and a single instrument holder 30. Then, the surgical device illustrated in FIGS. 1 and 2 is positioned on the operating table so as to rest on the longer sides of the feet. of the chassis 50, the assembly 10 of the hoops 1 being movable relative to the frame 50 along the X axis which is horizontal, in the configuration of Figure 4, the X axis is vertical. The arches 1 are for example positioned above the area provided for introducing the member to operate. Independently, the device illustrated in FIG. 4 does not include a tablet 60 fixed on the slides 15 movable along the Y axis which slide along the slides 66. FIG. 5 shows another variant of positioning of a device 100 without a tablet and resting on the longer sides of the legs 5 of the frame 50 placed on an operating table. The arches 1 are set above and below the operative site so as to surround the member to be operated not shown. As shown in FIGS. 4 and 5, the absence of a shelf 60 allows a greater angular variation in the positioning of the arches 1. FIG. 6 illustrates a variant of the instrument holder 30 comprising a hollow fixing portion 33 comprising a slit of shape and section corresponding to the hoop 1 so as to slide along thereof and a body 32 traversed by an open housing in which can be inserted and / or slide a trocar 150. The instrument holder 30 is maintained by friction in the desired position along the hoop 1 The trocar is held in the instrument holder by means known to those skilled in the art, in particular by jaw and / or pinch. This variant is particularly suitable for a corresponding camera trocar. FIG. 7 illustrates another example of an instrument holder 30 comprising an attachment portion 34 provided with two pads 33, here in the form of disks, slidable along the arch 1 that it sandwiches. The instrument holder comprises a system 30 of brakes allowing the fixing portion 34 to remain in position by clamping along the arch 1 The instrument holder 30 comprises body 32 with a housing adapted to receive a trocar for the passage of a surgical instrument. Optionally, the body 32 of the instrument holder 30 can be adjustable in translation and in rotation with respect to a W axis distinct from the Z axis, in particular perpendicular to the Z axis. FIG. member M to operate on the support 62 of a device according to the invention. The device 100 is similar to that of Figures 1 and 2. It comprises frame 50 having the shape of a square 40 cm side. The invention is not limited to a particular form of chassis. This may be rectangular, for example between 30 cm and 100 cm in size. The arches are arcs of circle whose radius is between 25cm and 50cm The pre-positioned device rests on the operating table by means of the two elongated and parallel feet 5. In the illustrated example, the surgical device 100 optionally includes a tablet 60 provided with a support 62 for receiving the member to operate, for example a hand. The support 62 and the shelf 60 form here a single piece, being for example made jointly by molding or assembly. After having marked with an opaque radio marker one or more points f on the member M, for example three points as illustrated, one obtains by medical imaging at least one image of the limb and the area to be operated. The imaging system calculates for example the positioning of the member M, arches, and instruments. The surgeon positions the member M on the support 62 according to the indications given by the imaging system. It checks the position with the laser pointer 300 as illustrated. The system checks and possibly corrects the position of each arches 1 and each instrument holder 30 to orient the instruments to the point to be treated located under the skin, at the intersection of the Z axes. The motorized system also regulates the position of the trocars in the instrument holders. Each element of the device 100, hoop, frame, can be made of metal including titanium, stainless steel, aluminum, or a rigid plastic material. The device can be sterilized, in particular several times.

The device 100 partially represented in FIG. 9 comprises a single hoop 1 having a complete circular ring shape. The hoop 1 is fixed to a hub 2, mobile in rotation about the axis R. The hoop 1 can rotate 360 ° about itself about the axis of rotation R, even when it bears two instrument holders 30 as illustrated. The arches of the surgical devices illustrated above have a section of flattened shape, including rectangular as shown in section in Figure 10A. In alternative embodiments a hoop may have a section of different shape, square as shown in Figure 10B.

A bow 1 may be composed of several tubes, for example two circular tubes of identical section as illustrated in Figures 10C and 10D or different as in Figure 10E, forming a geometric structure similar to rails. The tubes are for example adjacent as in Figure 10C or not. The arches illustrated are full, it is not out of the invention with hollow arches. During the procedure, both the holders carrying the camera and those carrying the surgical instruments and the corresponding arches can be manipulated by means of a motorized actuation system. The invention is not limited to the illustrated examples. For example, the number of arches may be different and the number of instrument holders on each arch.

The arches may be other than semicircles and have between their ends an angular deviation greater than 180 °. All degrees of freedom can be locked by a brake system. The phrase "having one" is synonymous with "having at least one".

Claims (12)

REVENDICATIONS1. Surgical device (100) comprising at least one hoop (1) movable in rotation around an axis (R) and adjustable in position about this axis and at least one instrument holder (30) movable along said at least one hoop (1) and adjustable in position thereon. 2. Device according to claim 1, comprising a single arch (1) or an assembly (10) of at least two arches (1) interconnected, in particular through a pivot axis (R). 3. Device according to claim 1 or 2, each instrument holder (30) having means for positioning the instrument axially along a proper axis (Z). 4. Device according to the preceding claim, the axes (Z) of axial displacement of the instrument carrier intersecting at a point (0) fixed relative to the or the arcs and axes (Z) pivoting about the point (0) in function of the movements of the arches and the instrument holders (30). 5. Device according to any one of the preceding claims, at least one of the arches (1) having the shape of a semicircle. 6. Device according to any one of the preceding claims, 20 having a frame (50) integral with the arch or hoops, the latter respectively being movable relative to said frame, in particular in translation along an axis (X). 7. Device according to the preceding claim, the chassis (50) comprising at least one fastening means (65) movable along a second axis (Y), in particular perpendicular to the axis (X), the fastening means (65) being configured to receive, removably or not, a tablet (60) for receiving the portion to be operated on a patient. 8. Device according to any one of the preceding claims, comprising at least one motorized actuation system (80), in particular controllable by a wireless link, arranged to move and hold in position at least one of the 30 arches (1). ), one of the instrument holders (30), a fixing means (15, 65), and / or a trocar (150) or an instrument (135) housed in an instrument holder (30). 9. Device according to any one of claims 2 to. 8, the assembly (10) comprising three arches. 10. Device according to any one of the preceding claims, comprising a laser pointer (300). 11. An instrument holder (30) for a surgical device (100) according to any one of the preceding claims including a system, particularly motorized, for moving and holding in position a trocar (150) or an instrument (135) housed in the instrument holder (30) and / or the instrument holder (30) on a bow (1) of the device (100). 12. A method for calculating the position of surgical instruments, particularly during laparoscopic, diagnostic or surgical intervention, using a surgical device (100) according to claim 10, including determining the focusing the surgery by performing an image by medical imaging and calculating, from this point, the position of each component of the device to orient the instruments to the point to be treated. 15