OPERATING HANDLE WITH FEEDBACK OF GUIDEWIRE/CATHETER ADVANCEMENT RESISTANCE FOR VASCULAR INTERVENTION ROBOT

Abstract

An operating handle with feedback of guidewire/catheter advancement resistance for a vascular intervention robot includes a sliding guide rail, a fixing base plate, a connecting rod, an operation rod, a pressure sensing device, a rotary driving device, and a linear motor. The rotary driving device, the sliding guide rail, and a stator of the linear motor are arranged on the fixing base plate. The pressure sensing device and a rotor of the linear motor are connected with the sliding guide rail through a slider and are able to reciprocate along the sliding guide rail. The connecting rod has one end provided with the operation rod and the other end connected with the rotor of the linear motor through a strain gauge. The connecting rod passes through the pressure sensing device and the rotary driving device in sequence.

Claims

1. An operating handle with a feedback of guidewire/catheter advancement resistance for a vascular intervention robot comprising a sliding guide rail, a fixing base plate, a connecting rod, an operation rod, a pressure sensing device, a rotary driving device, and a linear motor, wherein the rotary driving device, the sliding guide rail, and a stator of the linear motor are arranged on the fixing base plate; the pressure sensing device and a rotor of the linear motor are connected with the sliding guide rail through a slider and are configured to reciprocate along the sliding guide rail; and the connecting rod has a first end provided with the operation rod and a second end connected with the rotor of the linear motor through a strain gauge; and the connecting rod passes through the pressure sensing device and the rotary driving device in sequence.

2. The operating handle according to claim 1, wherein the pressure sensing device comprises a film-type pressure sensor, a first sliding bearing, and a rotary slip ring, wherein: the film-type pressure sensor is wrapped on a surface of the operation rod; the first sliding bearing and the rotary slip ring are arranged on the sliding guide rail; and the film-type pressure sensor is electrically connected with the rotary slip ring, and the rotary slip ring is externally connected with a main controller.

3. The operating handle according to claim 2, further comprising a second sliding bearing, the second sliding bearing is fixed to the fixing base plate, and the first sliding bearing and the second sliding bearing support the connecting rod.

4. The operating handle according to claim 1, wherein the rotary driving device comprises a fixing base, a rotary encoder, a rotary driving piece, and a rotary driving rod, the rotary encoder is provided on the fixing base; and the rotary driving rod is connected with a rotor of the rotary encoder; the rotary driving piece is fixed to the connecting rod and has two ends provided with connecting holes; and the rotary driving piece is connected with the rotary driving rod through the connecting holes; and the connecting rod is configured to drive the rotary driving piece to rotate so as to drive the rotary encoder to rotate through the rotary driving rod.

5. The operating handle according to claim 4, wherein the rotary driving piece is slidable on the rotary driving rod through the connecting holes.

6. The operating handle according to claim 1, further comprising a thrust bearing, wherein a first end of the thrust bearing is connected with the connecting rod and a second end of the thrust bearing is connected with the strain gauge.

7. The operating handle according to claim 1, wherein the linear motor is configured to transmit a moving distance and speed of the rotor of the linear motor to a main controller through a sensor.

8. The operating handle according to claim 7, wherein the sensor comprises a grating ruler, a magnetic grating ruler, a distance meter, or a printed circuit board (PCB) distance sensor.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] Other features, objectives, and advantages of the present disclosure will become more apparent by reading the detailed description of non-limiting embodiments with reference to the following drawings.

[0034] FIGS. 1 and 2 are structural views of an operating handle for a vascular intervention robot.

[0035] FIG. 3 is a control logic for force feedback of the operating handle.

REFERENCE NUMERALS

[0036] 1. film-type strain gauge; [0037] 2. supporting sliding bearing; [0038] 3. rotary slip ring; [0039] 4. connecting rod; [0040] 5. rotary driving rod; [0041] 6. rotary driving piece; [0042] 7. rotary encoder; [0043] 8. fixing base; [0044] 9. bidirectional thrust bearing; [0045] 10. strain gauge; [0046] 11. linear motor; [0047] 12. sliding guide rail; [0048] 13. fixing base plate; and [0049] 14. operation rod.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0050] The present disclosure is described in detail below with reference to specific embodiments. The following embodiments will help those skilled in the art to further understand the present disclosure but do not limit the present disclosure in any way. It should be noted that several variations and improvements can also be made by a person of ordinary skill in the art without departing from the concept of the present disclosure. These all fall within the protection scope of the present disclosure.

[0051] As shown in FIGS. 1 to 3, the present disclosure provides an operating handle for a vascular intervention robot that provides feedback of guidewire/catheter advancement resistance. The operating handle simulates operation actions of a surgeon in vascular interventional surgery and replicates the actions of the surgeon to advance and rotate a guidewire/catheter, so as to control the front-end intervention robot to complete gripping, advancement, and rotation of the guidewire/catheter. Since the operation actions of the surgeon include several actions, the operating handle needs to decouple the operation actions of the surgeon. A force sensor and a power actuator relay the resistance encountered by the guidewire/catheter in the blood vessel during the advancement process to the operating handle. The operating handle then transmits the resistance to the surgeon to help the surgeon determine whether the guidewire/catheter is advanced smoothly during the interventional operation. The present disclosure replicates the operation actions of the surgeon in vascular interventional surgery through a two-degree-of-freedom (2-DoF) mechanism that performs linear and rotational motions. Specifically, the operating handle includes a film-type strain gauge 1, a supporting sliding bearing 2, a rotary slip ring 3, a connecting rod 4, a rotary driving rod 5, a rotary driving piece 6, a rotary encoder 7, a fixing base 8, a bidirectional thrust bearing 9, a strain gauge 10, a linear motor 11, a sliding guide rail 12, a fixing base plate 13, and an operation rod 14. The sliding guide rail 12, a stator of the linear motor 11 and the fixing base 8 are fixed on the fixing base plate 13. The rotary slip ring 3, a rotor of the linear motor 11, and the sliding bearing 2 are connected with the sliding guide rail 12 through a slider and are movable linearly along the sliding guide rail 12. The rotary encoder 7 is hollow and fixed to the fixing base plate through the fixing base 8. The operation rod 14, the rotary driving piece 6, the bidirectional thrust bearing 9, and the strain gauge 10 are connected with the connecting rod 4. The connecting rod 4 is supported by the supporting sliding bearing 2 and is slidable linearly and rotatable in the supporting sliding bearing 2. The film-type strain gauge 1 is attached to a surface of the operation rod 14. The rotary driving piece 6 is fixed to the connecting rod 4 and has two ends provided with holes. The rotary driving piece 6 is connected with the rotary driving rod 5 through the holes and is slidable on the rotary driving rod 5 through the holes. The rotary driving rod 5 is connected with a rotor of the rotary encoder. The bidirectional thrust bearing 9 has one end connected with the connecting rod 4 and the other end connected with the strain gauge 10. The connecting rod 4 is connected with the rotor of the linear motor 11 through the strain gauge 10. Another strain gauge 10 is provided in a guidewire/catheter advancing mechanism of the distal intervention robot for measuring an advancing force applied on the guidewire/catheter during the advancing process.

[0052] In a variation of the present disclosure, the operating handle includes a film-type strain gauge 1, a supporting sliding bearing 2, a rotary slip ring 3, a connecting rod 4, a rotary encoder 7, a strain gauge 10, a linear motor 11, a fixing base 8, and a sliding guide rail 12. The sliding guide rail 12, a stator of the linear motor 11, and the fixing base 2 are fixed on the fixing base plate 13. The rotary slip ring 3, the rotary encoder 7, a rotor of the linear motor 11, and the supporting sliding bearing 2 are connected with the sliding guide rail 12 through a slider and are movable linearly along the sliding guide rail 12. The operation rod 14 and the rotary encoder 7 are connected with the connecting rod 4. The connecting rod 4 is supported by the supporting sliding bearing 2 and a rotating end of the rotary encoder 7 and is linearly slidable and rotatable in the supporting sliding bearing 2. The film-type strain gauge 1 is attached to a surface of the operation rod 14. A fixed end of the rotary encoder 7 is connected with the rotor of the linear motor 11 through the strain gauge 10.

[0053] The working principle of the present disclosure is as follows:

[0054] In endovascular interventional surgery, the surgeon needs to perform three basic actions to manipulate the guidewire/catheter: the surgeon's fingers grip/release the guidewire/catheter, the surgeon's hand advances the guidewire/catheter linearly, and the surgeon's fingers rotate the guidewire/catheter.

[0055] I: Gripping/releasing action of the surgeon's fingers. The surgeon holds the operation rod 14 and controls a gripping force. The film-type pressure sensor 1 wrapped on the surface of the operation rod 14 converts the surgeon's gripping force into a current signal and transmits the current signal to a main controller through the rotary slip ring 3. The main controller identifies the surgeon's gripping action based on the current signal transmitted by the film-type pressure sensor 1. When the film-type pressure sensor 1 detects a pressure, it indicates that the surgeon is performing a gripping action. Thus, a gripping mechanism of the distal intervention robot is controlled to grip the guidewire/catheter. When the film-type pressure sensor 1 detects no pressure, it indicates that the surgeon is performing a releasing action. Thus, the gripping mechanism of the distal intervention robot is controlled to release the guidewire/catheter. The film-type pressure sensor 1 detects the magnitude of the surgeon's gripping force through a magnitude of an analog signal, thereby adjusting the magnitude of the gripping force of the gripping mechanism of the distal intervention robot.

[0056] II: Linear advancing action of the surgeon's hand. The surgeon controls the guidewire/catheter to advance linearly by linearly pulling or pushing the connecting rod 4 by the operation rod 14. The connecting rod 4 drives the rotor of the linear motor 11 to move through the bidirectional thrust bearing 9. A ruler (or a magnetic grating ruler, a distance meter, or a printed circuit board (PCB) distance sensor) of the linear motor 11 transmits a moving distance and speed of the rotor to the main controller. The moving distance and speed of the rotor reflect the pushing distance and speed of the surgeon's hand, and the distance and speed of the guidewire/catheter advanced by an advancing mechanism of the distal intervention robot are controlled based on the moving distance and speed of the rotor.

[0057] III: Rotating action of the surgeon. The surgeon rotates the connecting rod 4 by rotating the operation rod 14, thereby controlling the rotation of the guidewire/catheter. The rotation of the connecting rod 4 drives the rotary driving piece 6 to rotate, thereby driving the rotary driving rod 5 to rotate. The rotation of the rotary driving rod 5 drives the rotary encoder 7 to rotate. The rotary encoder acquires and transmits the angle and speed of the surgeon's rotating action to the main controller, so as to control the angle and speed of a rotating mechanism of the distal intervention robot to rotate the guidewire/catheter.

[0058] The advancing mechanism of the distal intervention robot is further provided therein with a strain gauge. The strain gauge detects the resistance of the guidewire/catheter during the advancing process, and transmits the resistance to the main controller in the form of an electrical signal. The main controller adjusts the current of the linear motor 11 according to the front-end resistance to generate a corresponding push or pull force until the current value acquired by the strain gauge 10 is equal to the current value measured by a front-end strain gauge. Since the surgeon is controlling the operation rod 14, the push/pull force of the linear motor is relayed to the surgeon through the connecting rod. As a result, the surgeon's hand experiences a resistance similar to that encountered in a real scenario of physically advancing the guidewire/catheter.

[0059] In the present disclosure, the linear motor 11 is configured to measure the operating displacement and transmit the resistance of the guidewire/catheter. The linear motor 11 measures the pushing distance of the surgeon by transmitting its position. The linear motor drives the operation rod to automatically return to a central position through its position control mode and relays the advancing force to the surgeon through its torque control mode. The present disclosure solves the problems that the multi-DoF motion of the decoupling mechanism of the rotary slip ring 3, the crank-like rocker mechanism, and the direct thrust bearing (or magnet) conflicts with the single-DoF motion of a single component and that the cords may become tangled. The present disclosure decouples the movement of the gripping force sensor and the restraint of the fixed cord through the hollow rotary slip ring 3. The gripping force sensor is fixedly connected with the operation rod and is movable linearly and rotationally with the operation rod, and the lead wires of the gripping force sensor are also movable with the operation rod. The present disclosure solves the problem of cord tangling by decoupling the rotational motion and the linear motion through the hollow rotary slip ring 3. The present disclosure decouples the movement of the operation rod and the rotational movement of the rotary encoder 7 through the sliding bearing and the crank structure. The connecting rod 4, the rotary driving piece 6 and the rotary driving rod 5 form the crank structure, which can measure the rotation angle and speed of the connecting rod 4 without disturbing the linear motion of the connecting rod 4. The present disclosure decouples the rotational motion of the operation rod and the linear motion of the linear motor 11 through the bidirectional thrust bearing 9 or a magnet. The connecting rod 4 can perform linear motion and rotational motion, that is, 2-DOF motion, while the linear motor 11 can only perform linear motion. Therefore, the present disclosure decouples the 2-DOF motion of the connecting rod 4 and the single-DOF motion of the linear motor 11 through the bidirectional thrust bearing 9 or the magnet.

[0060] The specific embodiments of the present disclosure are described above. It should be understood that the present disclosure is not limited to the above specific implementations, and a person skilled in the art can make variations or modifications within the scope of the claims without affecting the essence of the present disclosure. The embodiments in the present disclosure and features in the embodiments may be combined with each other in a non-conflicting situation.