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JP2007202950A - Leg holding tool for surgery robot - Google Patents

Leg holding tool for surgery robot Download PDF

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Publication number
JP2007202950A
JP2007202950A JP2006028259A JP2006028259A JP2007202950A JP 2007202950 A JP2007202950 A JP 2007202950A JP 2006028259 A JP2006028259 A JP 2006028259A JP 2006028259 A JP2006028259 A JP 2006028259A JP 2007202950 A JP2007202950 A JP 2007202950A
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lower limb
side fixing
knee joint
surgical robot
fixing portion
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Koichi Kuramoto
孝一 藏本
Kunihiko Fujiwara
邦彦 藤原
Takayuki Inoue
貴之 井上
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Nakashima Propeller Co Ltd
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Nakashima Propeller Co Ltd
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Priority to JP2006028259A priority Critical patent/JP2007202950A/en
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a leg holding tool which firmly fixes the knee joint of a patient without narrowing the work area of a surgery robot when performing a knee joint replacement surgical operation using the surgery robot. <P>SOLUTION: In the leg holding tool for the surgery robot which holds, by maintaining the angle of the knee joint at a predetermined angle, the leg of the patient placed on an operating table, this leg holding tool has two hinge + sliding mechanisms which can freely regulate the angle and spacing of a tibia side fixing portion which wraps the tibia by exposing the knee joint and a thighbone side fixing portion which wraps a thighbone and the operating table of each of the tibia side fixing portion and the thighbone side fixing portion, and a hinge/sliding mechanism which is connected by freely regulating the angle and spacing between the tibia side fixing portion and the thighbone side fixing portion. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

本発明は、手術ロボットを用いての人工膝関節置換術の際、骨切除を安全、かつ正確に行うために患者の膝関節を固定する手術ロボット用下肢把持治具に関するものである。   The present invention relates to a lower limb gripping jig for a surgical robot that fixes a patient's knee joint in order to perform bone resection safely and accurately during an artificial knee joint replacement using a surgical robot.

一般に、膝関節の損傷に対し、大腿骨遠位部、脛骨近位部の関節面を表面置換するように人工膝関節置換術が施される。これにおいて、大腿骨側は、大腿骨遠位面形状類似の金属製コンポーネント(大腿骨コンポーネント)を用い、脛骨側は、超高分子量ポリエチレン製プレート単体又は金属製のプレートと併用したもの(脛骨プレート)を用いて膝関節に置換される。   In general, for knee joint damage, artificial knee joint replacement is performed so that the joint surfaces of the distal femur and proximal tibia are replaced. In this, a metal component (femoral component) similar to the shape of the distal femur is used on the femur side, and an ultrahigh molecular weight polyethylene plate alone or in combination with a metal plate (tibial plate) on the tibia side ) To replace the knee joint.

人工膝関節置換術において、人工膝関節を大腿骨と脛骨に置換する際には、大腿骨コンポーネントと脛骨プレートの設置面の形状に合わせて大腿骨と脛骨の骨端を切除し、その切除面とそれぞれの設置面を密着させて固定する。この固定には骨セメントを使用する方法と使用しない方法がある。   When replacing the artificial knee joint with the femur and tibia in artificial knee joint replacement, the femoral component and tibial bone edges are excised according to the shape of the femoral component and tibial plate placement surface, and the resection surface is removed. And fix each installation surface in close contact. This fixation can be done with or without bone cement.

骨セメントを使用する場合には、セメント層の厚みを一定に保つことが応力分散効果をもたらし、長期安定した固定を可能とする。また、骨セメントを使用しない方法では、設置面を多孔面としてその多孔面に骨を自然成長させて絡み付かせる投錨効果で固定力を得る。この双方の固定においても、人工膝関節設置面と骨側の切除面の高い一致性が重要となる。   When bone cement is used, keeping the thickness of the cement layer constant brings about a stress dispersion effect and enables stable long-term fixation. Moreover, in the method which does not use bone cement, a fixing force is obtained by the anchoring effect in which the installation surface is a porous surface and the bone is naturally grown and entangled with the porous surface. In both of these fixations, high consistency between the artificial knee joint placement surface and the bone-side cut surface is important.

一般的な手術では、人工膝関節設置面のための骨を切除する際には、スリットを有するカッティングガイドと呼ばれる器械を使用し、そのスリットにボーンソーと呼ばれる刃物を挿入して、そのスリットを基準面として切除を実施する。この際に、スリットとボーンソー間の隙間やボーンソーの切除中のたわみ等により、正確な切除は困難であった。   In general surgery, when cutting the bone for the artificial knee joint placement surface, an instrument called a cutting guide with a slit is used, and a blade called a bone saw is inserted into the slit and the slit is used as a reference. Perform excision as a plane. At this time, accurate excision was difficult due to a gap between the slit and the bone saw or deflection during the bone saw excision.

一方で、人工膝関節の設置位置は、臨床学的に最適な位置に設置する必要がある。設置位置誤差が生じると、膝関節可動域制限又は軟部組織(特に、膝関節側副靭帯)のバランス不均衡を生じ、人工膝関節に過度の応力をもたらして早期に破壊を引き起こす。   On the other hand, it is necessary to install the artificial knee joint at a clinically optimal position. When an installation position error occurs, the range of motion of the knee joint is limited or the soft tissue (particularly, the collateral ligament of the knee joint) is imbalanced, causing excessive stress to the knee prosthesis and causing early destruction.

この人工膝関節の設置位置においては、膝関節の限られた視野空間から様々な器械を使用して医師の術中の経験と勘により、人工膝関節設置位置が決定されている。このような曖昧さにより、人工膝関節設置位置に誤差を生じ、人工膝関節の早期破壊をきたす場合がある。   As for the position of the artificial knee joint, the position of the artificial knee joint is determined based on the experience and intuition of the doctor during operation using various instruments from the limited visual field of the knee joint. Such ambiguity may cause an error in the position of the artificial knee joint, which may cause early destruction of the artificial knee joint.

この手作業による大腿骨、脛骨を切除する際の誤差要因を排除するために、下記特許文献1に例示されるような手術ロボット(骨切除装置)が考案された。この手術ロボットにより、人工膝関節の正確な設置や正確な骨切除による骨との密着性が実現し、人工膝関節の長期にわたる機能を確保することができる。   In order to eliminate an error factor when excising the femur and tibia by this manual operation, a surgical robot (bone resection device) as exemplified in Patent Document 1 below has been devised. With this surgical robot, accurate placement of the artificial knee joint and adhesion to the bone by accurate bone resection are realized, and the long-term function of the artificial knee joint can be ensured.

ところで、従来の手術では骨切除の際に、補助者が患者の下肢を押えて固定し、術者が骨切除を行うのが一般的である。手術ロボットによる切除では、ロボットの可動域をある程度確保する必要性があることから、切除中に下肢を押える補助者が介在するのは困難である。   By the way, in the conventional operation, at the time of bone resection, an assistant generally pushes and fixes a patient's lower limb, and an operator performs bone resection. In excision with a surgical robot, it is necessary to secure a certain range of motion of the robot, and therefore it is difficult for an assistant to press the lower limb during the excision.

さらに、手術ロボットでは、工具と患部の切除位置の相対関係が切除面を定義するため、手術ロボットによる位置決めを遂行した後及び骨切除中には患部を不動で強固に固定することが要求されるが、人間による補助者ではその遂行は困難である。   Furthermore, in the surgical robot, since the relative relationship between the cutting position of the tool and the affected part defines the cutting surface, it is required to fix the affected part firmly and firmly after performing the positioning by the surgical robot and during the bone resection. However, it is difficult for human assistants to do so.

したがって、下記特許文献2に例示されるように、手術ロボットによる骨切除中に下肢を強固に固定する器具が考案されている。この器具を用いる方法では、骨を器具により直接把持することとなるが、骨切除面近傍では、切除用工具又は手術ロボットとの干渉により、相応のスペースを有する機構を設けることは困難であり、把持部は切除面から離れた位置となる。   Therefore, as exemplified in Patent Document 2 below, an instrument for firmly fixing the lower limb during bone resection by a surgical robot has been devised. In the method using this instrument, the bone is directly gripped by the instrument, but it is difficult to provide a mechanism having an appropriate space near the bone resection surface due to interference with the resection tool or the surgical robot. The grip portion is at a position away from the cut surface.

このような把持位置においては、骨を直接把持する把持部を確保するために皮切量が通常の手術よりも増大する。その結果、患部の治癒が遅延化し、ひいては周囲組織の過大な損傷により、術後合併症を引き起こす可能性が高いという問題点を有している。   In such a gripping position, the amount of skin incision increases as compared with a normal operation in order to secure a gripping part that directly grips the bone. As a result, there is a problem that healing of the affected area is delayed and, as a result, there is a high possibility of causing postoperative complications due to excessive damage of surrounding tissues.

また、手術ロボットでは、骨切除を遂行する工具と患部の相対位置を把握する必要があるが、この際にX線透視装置を用いて骨格透視画像を取得し、ロボットに内在する骨格CADデータと照合する手法が採用される場合がある。   In addition, in a surgical robot, it is necessary to grasp the relative position between a tool for performing bone resection and an affected part. At this time, a skeleton fluoroscopic image is acquired using an X-ray fluoroscope, A matching method may be employed.

このため透視画像撮影時には、X線透視装置と手術ロボット及び患部の相対位置を固定する必要があり、さらに、鮮明な骨格画像を取得するには、患部と手術ロボットの相対位置を正確に計測することが寄与する。このため、患部を強固に固定し、その上でX線を透過させて良好な透視画像を取得することが必要である。
特開2002−306500号公報 特開2003−024338号公報
For this reason, it is necessary to fix the relative positions of the X-ray fluoroscopic apparatus, the surgical robot, and the affected part at the time of fluoroscopic image capturing. Further, in order to obtain a clear skeleton image, the relative position of the affected part and the surgical robot is accurately measured. That contributes. For this reason, it is necessary to firmly fix the affected part and transmit X-rays thereon to obtain a good fluoroscopic image.
JP 2002-306500 A Japanese Patent Laid-Open No. 2003-024338

本発明は、手術ロボットを用いて人工膝関節置換術の骨切除を行う際、膝角度を所望のものにして強固に固定することにより、安全に手術が遂行でき、かつ皮切量を極力低減させるための下肢把持治具を提供し、医師の計画通りの正確な骨切除・手術を達成することを目的としている。   In the present invention, when performing bone resection for artificial knee joint replacement using a surgical robot, it is possible to safely perform the operation and reduce the amount of skin incision as much as possible by firmly fixing the knee angle to a desired value. The aim is to provide a lower limb gripping tool for achieving the accuracy of bone resection and surgery as planned by the doctor.

一方で、手術ロボットを使用して骨切除を実施する場合、患部と手術ロボットの先端工具の相対位置を決定する際にX線透視装置を使用する手法を採用した場合に、患部を強固に固定し、かつX線高透過材料で構成される下肢固定具を提供することにある。   On the other hand, when bone excision is performed using a surgical robot, when the technique of using an X-ray fluoroscope is used to determine the relative position of the affected part and the tip tool of the surgical robot, the affected part is firmly fixed. And it is providing the leg fixing device comprised with an X-ray highly transparent material.

このために、本発明による下肢把持治具は、請求項1に記した、手術台上に載せられた患者の下肢を膝関節の角度を所定に保持して把持する手術ロボット用下肢把持治具であり、この下肢把持治具が、間に膝関節を露出させて脛骨を包む脛骨側固定部及び大腿骨を包む大腿骨側固定部と、脛骨側固定部、大腿骨側固定部それぞれの手術台との角度と間隔を自由に調節可能な二つのヒンジ機構+スライド機構と、脛骨側固定部と大腿骨側固定部を角度と間隔を自由に調節して連結するヒンジ・スライド機構とを有することを特徴とするものである。   To this end, the lower limb grasping jig according to the present invention is the lower limb grasping jig for a surgical robot for grasping the patient's lower limb placed on the operating table while maintaining the knee joint angle at a predetermined angle. The lower limb grasping jig is exposed to the knee joint between the tibial side fixing part that wraps the tibia, the femoral side fixing part that wraps the femur, the tibial side fixing part, and the femoral side fixing part. It has two hinge mechanisms + slide mechanism that can freely adjust the angle and distance between the base and a hinge / slide mechanism that connects the tibial side fixing part and the femoral side fixing part by freely adjusting the angle and distance. It is characterized by this.

また、この下肢把持治具の具体例として、請求項2に記した、手術台の側方に付設されるレールに脛骨側部材及び大腿骨側部材をスライド可能に取り付けるとともに、脛骨側部材及び大腿骨側部材に各ヒンジ・スライド機構のそれぞれベース部を連結したもの、請求項3に記した、脛骨側固定部と脛骨の間及び大腿骨側固定部と大腿骨の間に流体の流入出によって膨張、収縮する袋を介在させたもの、請求項4に記した、この下肢把持治具がX線高透過材料で構成されるものが考えられる。   As a specific example of the lower limb grasping jig, the tibial side member and the femoral side member are slidably attached to the rail attached to the side of the operating table, and the tibial side member and the thigh The base part of each hinge / sliding mechanism is connected to the bone side member, and the inflow and outflow of fluid between the tibial side fixing part and the tibia and between the femoral side fixing part and the femur described in claim 3. An inflatable and deflating bag is interposed, and the lower limb gripping jig described in claim 4 is composed of an X-ray highly transparent material.

本発明に係る下肢把持治具によって下肢を把持すれば、手術個所である患部を強固に固定できることで、患部と手術ロボット工具との相対位置を正確に定義できるとともに、切除中の加工反力による変位を防止し、正確な骨切除を達成する。また、手術ロボットによる骨切除では、ロボットの稼動範囲中に補助者が介在することは困難であるが、本発明の下肢把持治具により、補助者を介在させることなく、安全に骨切除が遂行できる。   If the lower limb is gripped by the lower limb gripping jig according to the present invention, the affected part that is the surgical site can be firmly fixed, so that the relative position between the affected part and the surgical robot tool can be accurately defined, and the processing reaction force during resection Prevent displacement and achieve accurate bone resection. In addition, bone removal with a surgical robot makes it difficult for an assistant to intervene in the operating range of the robot. However, the present invention can safely perform bone resection without using an assistant with the lower limb gripping jig. it can.

さらに、従来の下肢固定方法では、手術中の作業領域を確保するための皮切に加えて、下肢をクランプ状の器具で把持するための領域を確保する必要があり、そのために余分な皮切を要したが、本発明の下肢把持治具では、必要最低限の部材のみを患部周辺に配置するにとどまり、そのような余分な皮切を要せず、低侵襲手術により患者の早期回復が可能となる。   Further, in the conventional lower limb fixation method, in addition to the skin incision for securing the work area during the operation, it is necessary to secure an area for grasping the lower limb with a clamp-like instrument. However, in the lower limb grasping jig of the present invention, only the minimum necessary members are arranged around the affected area, and such an extra skin cut is not required, and the patient can be recovered early by minimally invasive surgery. It becomes possible.

また、手術ロボットと患部の相対位置を決定する際に、X線透視装置を用いた記憶装置内のCADモデルとのマッチングを行う手法によるときは、患部を強固に固定して良好な透視画像が得られるため、正確な相対位置の確定が可能となる。   Further, when determining the relative position of the surgical robot and the affected area, when using a method of matching with a CAD model in a storage device using an X-ray fluoroscopic apparatus, the affected area is firmly fixed and a good fluoroscopic image is obtained. As a result, it is possible to determine an accurate relative position.

図1は、手術ロボットを使用した人工膝関節置換術における骨切除の際の模式図であって、手術台110と、手術台の上に載せられる患者40と、患者40の下肢を把持して膝角度を固定する下肢把持治具50と、手術ロボット60及び記憶装置70が設置されている。   FIG. 1 is a schematic diagram of bone resection in an artificial knee joint replacement using a surgical robot, and grasps an operating table 110, a patient 40 placed on the operating table, and a lower limb of the patient 40. A lower limb gripping jig 50 for fixing the knee angle, a surgical robot 60, and a storage device 70 are installed.

まず、手術の開始に際して患者の患部(膝関節)の皮切を実施し、人工膝関節設置を施す大腿骨遠位端、脛骨近位端を手術に必要な必要最小限の量だけ露出させる。   First, at the start of the operation, the affected part (knee joint) of the patient is cut, and the distal end of the femur and the proximal end of the tibia where the artificial knee joint is placed are exposed by the minimum amount necessary for the operation.

次に、本発明の下肢把持治具50にて膝関節部を固定する。この操作における固定を図2の側面図とともに詳しく説明する。   Next, the knee joint is fixed by the lower limb gripping jig 50 of the present invention. The fixing in this operation will be described in detail with reference to the side view of FIG.

図2に示すように、本発明による下肢把持治具50は、脛骨を包む脛骨側固定部1と、大腿骨を包む大腿骨側固定部2とが間に露出させた膝関節を挟んで設けられる。これにおける両固定部1、2は、剛体からなるシェル状をした半筒体であり、それぞれ脛骨と大腿骨の下半分にあてがわれる。そして、両固定部1、2の下部には、手術台110との角度と間隔を自由に調節できる二つのヒンジ機構3、4+スライド機構7、8が設けられる。本例のヒンジ機構3、4+スライド機構7、8は、クランク状をした部材であり、下部にヒンジ機構3、4が、上部にスライド機構7、8が設けられたものである。さらに、両固定部1、2の上部には、この両固定部1、2を角度と間隔を自由に調節して連結するヒンジ・スライド機構6、5、14が設けられる。   As shown in FIG. 2, a lower limb grasping jig 50 according to the present invention is provided with a knee joint sandwiched between a tibial fixing portion 1 that wraps the tibia and a femoral side fixing portion 2 that wraps the femur. It is done. Both the fixing portions 1 and 2 are shell-shaped half cylinders made of a rigid body, and are respectively applied to the lower tibia and the lower half of the femur. Two hinge mechanisms 3, 4 + slide mechanisms 7, 8 that can freely adjust the angle and interval with the operating table 110 are provided below the fixed portions 1, 2. The hinge mechanisms 3 and 4 + sliding mechanisms 7 and 8 of this example are crank-shaped members. The hinge mechanisms 3 and 4 are provided at the lower part, and the sliding mechanisms 7 and 8 are provided at the upper part. Furthermore, hinge / sliding mechanisms 6, 5, 14 are provided on the upper portions of the two fixing portions 1, 2 to connect the two fixing portions 1, 2 by adjusting their angles and intervals freely.

まず、固定の際に患者の脚の長さに合わせて治具の長さが調整される。この長さの調整は、スライド機構7、8によって実現され、固定用クランプ9によって固定される。この際に両固定部1、2は、脛骨及び大腿骨の固定に寄与する部分であり、骨切除の際には大脛骨近位部、大腿骨遠位部に加工反力が作用することになるので、極力脛骨近位部、大腿骨遠位部付近に両固定部1、2を配置できるように調整する。この調整により、より強固な患部の固定が達成される。   First, the length of the jig is adjusted in accordance with the length of the patient's leg during fixation. The adjustment of the length is realized by the slide mechanisms 7 and 8 and is fixed by the fixing clamp 9. At this time, both the fixing portions 1 and 2 are portions that contribute to the fixation of the tibia and the femur, and a processing reaction force acts on the proximal portion of the large tibia and the distal portion of the femur during bone resection. Therefore, it adjusts so that both the fixing | fixed part 1 and 2 can be arrange | positioned to the proximal part of the tibia and the distal part of the femur as much as possible. By this adjustment, more firmly fixing the affected area is achieved.

次に、膝関節の角度の調整を実施する。人工膝関節置換術時の人工膝関節設置のための骨切除は、既存の人工膝関節では大腿骨側は前面、前斜面、遠位面、後斜面、後面の5面、脛骨側は近位面1面を切除する必要がある。特に、図3の模式図に示すように通常の皮切では膝蓋骨の周囲を切除するアプローチが行われるため、大腿骨の遠位面から後面を十分に露出しないと骨切除が達成できない。   Next, the knee joint angle is adjusted. Bone resection for artificial knee joint placement at the time of artificial knee joint replacement is the front, the front slope, the distal face, the rear slope, the rear face, and the tibia side are proximal in the existing artificial knee joint It is necessary to cut one surface. In particular, as shown in the schematic diagram of FIG. 3, in an ordinary skin incision, an approach of resecting the periphery of the patella is performed. Therefore, bone resection cannot be achieved unless the posterior surface is sufficiently exposed from the distal surface of the femur.

そこで、図2において、手術台110と両ヒンジ機構3、4のベース部10、11が相対移動できる機構と、足裏及び股関節付近に両ヒンジ機構3、4を設けて任意の角度が調整できる機構とした。本実施例では、手術台110の側方に付設されたレール111にスライド可能に取り付けられる脛骨側部材12及び大腿骨側部材13をそれぞれのベース部10、11と適宜な連結材で連結し、手術台110に対して両ヒンジ機構3、4が相対運動する構造となっている。   Therefore, in FIG. 2, the operating table 110 and the base portions 10 and 11 of the hinge mechanisms 3 and 4 can be moved relative to each other, and the hinge mechanisms 3 and 4 can be provided in the vicinity of the sole and the hip joint to adjust an arbitrary angle. The mechanism. In this embodiment, the tibial side member 12 and the femoral side member 13 that are slidably attached to the rail 111 attached to the side of the operating table 110 are connected to the base portions 10 and 11 with appropriate connecting materials, Both hinge mechanisms 3 and 4 are structured to move relative to the operating table 110.

このような構成をとるのは、手術台110に直接ベース部10、11を取り付けると、その存在スペースによって手術ロボット60やX線透視装置の作動に支障を来すことから、これを避けたものである。この点で、ベース部10、11は、各ヒンジ機構3、4のベースとなり得る最小限のスペースのもので足りる。   The reason for adopting such a configuration is that if the base portions 10 and 11 are directly attached to the operating table 110, the operation space of the operating robot 60 and the X-ray fluoroscopic apparatus is hindered by the presence space. It is. In this respect, the base portions 10 and 11 need only have a minimum space that can serve as a base for the hinge mechanisms 3 and 4.

さらに、膝屈曲の際の屈曲中心は個体差があり、一意的に回転中心を決定できないため、大腿骨遠位・脛骨近位部の距離を自由に設定可能なヒンジ・スライド機構5、6を設けた。大腿骨側のヒンジ・スライド機構5からは棒状部材15が延びており、これが脛骨側のヒンジ・スライド機構6、14に通される構成にしている(大腿骨側と脛骨側とが反対の構成であってもよい)。これにより、両固定部1、2の角度と間隔は自由に調節されるものとなり、図4の動き模式図に示すように任意の位置姿勢に設定可能となっている。最後に、上記の調整が完了した段階で、クランプ9にて位置を固定、不動とする。   Further, since the flexion center at the time of knee flexion varies among individuals and the rotation center cannot be uniquely determined, the hinge / slide mechanism 5, 6 that can freely set the distance between the distal femur and the proximal tibia is provided. Provided. A rod-like member 15 extends from the femoral side hinge / sliding mechanism 5, and is configured to pass through the tibial side hinge / sliding mechanisms 6 and 14 (a configuration in which the femoral side and the tibial side are opposite to each other). May be). As a result, the angles and intervals of the fixed portions 1 and 2 can be freely adjusted, and can be set to an arbitrary position and orientation as shown in the movement schematic diagram of FIG. Finally, when the above adjustment is completed, the clamp 9 fixes the position and does not move.

最終的な患部の固定の際には、患者の足を上記の固定された位置にて下肢把持治具50に設置した際に、両固定部1、2に同じく半筒体のシェル状をしたそれぞれの上蓋16、17を合わせて下肢を包み込み、両固定部1、2と両上蓋16、17の間に流体(圧縮空気・水・砂)が流入出可能な内部が空洞の袋を配置する。なお、両固定部1、2と両上蓋16、17との合わせ構造は、フックとロック機構を有するものでもよい。   In the final fixation of the affected area, when the patient's feet were placed on the lower limb gripping jig 50 at the above fixed position, both the fixed parts 1 and 2 were also formed in a half-cylindrical shell shape. The upper lids 16 and 17 are combined to wrap the lower limbs, and a hollow bag is disposed between the fixed portions 1 and 2 and the upper lids 16 and 17 so that fluid (compressed air, water, and sand) can flow in and out. . In addition, the combined structure of the both fixing portions 1 and 2 and the upper lids 16 and 17 may have a hook and a lock mechanism.

上記の設定が完了した段階で、図5の説明図に例示するように剛体の両固定部1、2及び両上蓋16、17と脚間で内部が空洞の袋80内の空間81に管18より圧縮空気を流入させて膨張させ、脚の筋肉や皮膚等の軟部組織31及び大腿骨30を含めて圧迫力を作用させ固定する。また、内部が空洞の袋80内の空間81に砂状メディアを配置して固定する場合には、メディアの量を調整し、袋80を脚の形状に膨張させて管18から袋内空気を抜き袋の形状を固定させて脚を固定する。図5の例示は大腿骨の場合であるが、脛骨20固定の際も同様の操作にて可能である。   When the above setting is completed, as shown in the explanatory diagram of FIG. 5, the pipe 18 is inserted into the space 81 in the bag 80 having a hollow inside between the rigid fixed portions 1 and 2 and the upper lids 16 and 17 and the legs. The compressed air is further inflated by inflow, and the compression force is applied and fixed including the soft tissue 31 and the femur 30 such as leg muscles and skin. Further, when sand-like media is disposed and fixed in the space 81 in the bag 80 having a hollow inside, the amount of the media is adjusted, the bag 80 is inflated into a leg shape, and air in the bag is drawn from the tube 18. Fix the shape of the bag and fix the legs. The illustration of FIG. 5 is the case of the femur, but the same operation can be performed when the tibia 20 is fixed.

上記の固定原理は、脚の広範囲な領域を固定に寄与させるため、骨の切削時の加工反力に対して十分な固定力を確保することが可能となる。   Since the above-described fixing principle contributes to fixing a wide area of the leg, it is possible to secure a sufficient fixing force with respect to a processing reaction force during bone cutting.

補助的な固定として、膝関節下は足首部付近を帯又はそれと同等の部材を用いて下肢把持治具と固定する。膝関節上は、脚は股関節部で患者の体幹部と固着しているため、患者が過度に動かないように配慮すればよい。さらに、大腿骨又は脛骨において、加工反力により骨の長軸周りに回転変位が危惧される場合には、補助的に下肢把持治具と一体化されたピンを脛骨近位部又は大腿骨遠位部に挿入して補助固定を施してもよい。   As an auxiliary fixation, under the knee joint, the vicinity of the ankle is fixed to the lower limb grasping jig using a belt or a member equivalent thereto. On the knee joint, since the leg is fixed to the patient's trunk at the hip joint, care should be taken so that the patient does not move excessively. In addition, in the femur or tibia, if rotational displacement is feared around the long axis of the bone due to processing reaction force, a pin that is supplementarily integrated with the lower limb grasping jig is attached to the proximal part of the tibia or the distal part of the femur. Auxiliary fixing may be performed by inserting into the part.

上記の患部固定が完了した段階で、図1における手術ロボット60を設置する。手術ロボットの工具と患部相対位置決定の際にX線透視装置を使用する際には、上記下肢把持治具をアルミニウム、チタン又は樹脂といったX線高透過性の材料で構成することにより、手術ロボットの基準位置と患部骨格画像が良好に取得され、手術ロボット内の記憶装置70内の患部骨格データと照合することで正確な相対位置の決定が達成される。   When the above-mentioned fixation of the affected area is completed, the surgical robot 60 in FIG. 1 is installed. When using an X-ray fluoroscopy device for determining the relative position of the surgical robot tool and the affected area, the surgical robot is constructed by configuring the lower limb gripping jig with a material having high X-ray permeability such as aluminum, titanium, or resin. The reference position and the affected part skeleton image are acquired well, and the correct relative position is determined by collating with the affected part skeleton data in the storage device 70 in the surgical robot.

さらに、手術中にX線透視でその他インプラント部品の挿入状況を確認する際にも、下肢を固定したまま撮影画像が取得でき、下肢把持治具を外すことなく即座に手術が続行できる点でも有利である。   Furthermore, when confirming the insertion status of other implant parts by fluoroscopy during surgery, it is advantageous in that the captured image can be acquired with the lower limbs fixed and the operation can be continued immediately without removing the lower limb grasping jig. It is.

これら一連の作業を経て、手術ロボットによる人工膝関節置換のための骨切除が行われる。この骨切除の際にも、上記方法により患部は強固に固定されるため、ロボットによる高精度な骨切除、正確な人工関節の設置が達成される。なお、この下肢把持治具は、マニュアル手術の際にも有用であるのはもちろんである。   Through these series of operations, bone excision for replacement of an artificial knee joint by a surgical robot is performed. Also at the time of bone resection, the affected part is firmly fixed by the above method, so that high-precision bone resection by a robot and accurate placement of an artificial joint can be achieved. Needless to say, this lower limb gripping jig is also useful during manual surgery.

本発明による手術ロボット用下肢把持治具を用いた手術の模式図である。It is a schematic diagram of a surgery using the lower limb gripping jig for a surgical robot according to the present invention. 本発明による手術ロボット用下肢把持治具の詳細図である。It is a detailed view of a lower limb gripping jig for a surgical robot according to the present invention. 人工膝関節置換術における膝角度と骨切除の可否の関係を示した説明図図である。It is explanatory drawing which showed the relationship between the knee angle in the knee arthroplasty and the possibility of bone resection. 本発明の手術ロボット用下肢把持治具の機構原理を示した説明図である。It is explanatory drawing which showed the mechanism principle of the lower limb holding jig for surgical robots of this invention. 本発明の手術ロボット用下肢把持治具の患部固定原理を示した説明図である。It is explanatory drawing which showed the affected part fixation principle of the lower limb holding jig for surgical robots of this invention.

符号の説明Explanation of symbols

1 脛骨側固定部
2 大腿骨側固定部
3 脛骨側ヒンジ機構
4 大腿骨側ヒンジ機構
5 大腿骨側ヒンジ・スライド機構
6 脛骨側ヒンジ・スライド機構
7 脛骨側スライド機構
8 大腿骨側スライド機構
9 クランプ
10 脛骨側ベース部
11 大腿骨側ベース部
12 脛骨側部材
13 大腿骨側部材
14 脛骨側ヒンジ・スライド機構
15 棒状部材
16 脛骨側上蓋
17 大腿骨側上蓋
18 管
20 脛骨
30 大腿骨
31 軟部組織
40 患者
50 下肢把持治具
60 手術ロボット
70 手術ロボットの記憶装置
80 袋
81 袋の空間
110 手術台
111 レール
DESCRIPTION OF SYMBOLS 1 Tibial side fixing | fixed part 2 Femur side fixing | fixed part 3 Tibial side hinge mechanism 4 Femur side hinge mechanism 5 Femur side hinge and slide mechanism 6 Tibial side hinge and slide mechanism 7 Tibial side slide mechanism 8 Femoral side slide mechanism 9 Clamp DESCRIPTION OF SYMBOLS 10 Tibial side base part 11 Femur side base part 12 Tibial side member 13 Femur side member 14 Tibial side hinge slide mechanism 15 Bar-shaped member 16 Tibial side upper lid 17 Femoral side upper lid 18 Pipe 20 Tibial 30 Femur 31 Soft part tissue 40 Patient 50 Lower limb gripping jig 60 Surgical robot 70 Surgical robot storage device 80 Bag 81 Bag space 110 Operating table 111 Rail

Claims (4)

手術台上に載せられた患者の下肢を膝関節の角度を所定に保持して把持する手術ロボット用下肢把持治具であり、この下肢把持治具が、間に膝関節を露出させて脛骨を包む脛骨側固定部及び大腿骨を包む大腿骨側固定部と、脛骨側固定部、大腿骨側固定部それぞれの手術台との角度と間隔を自由に調節可能な二つのヒンジ機構+スライド機構と、脛骨側固定部と大腿骨側固定部を角度と間隔を自由に調節して連結するヒンジ・スライド機構とを有することを特徴とする手術ロボット用下肢把持治具。   This is a lower limb gripping jig for a surgical robot that holds the patient's lower limb placed on the operating table while maintaining the knee joint angle at a predetermined angle, and this lower limb gripping jig exposes the knee joint between the tibia. Two hinge mechanisms + sliding mechanisms capable of freely adjusting the angle and interval between the tibial side fixing part for wrapping and the femoral side fixing part for wrapping the femur, and the operating table of each of the tibial side fixing part and the femoral side fixing part A lower limb grasping jig for a surgical robot, comprising: a hinge / sliding mechanism for connecting the tibial side fixing portion and the femur side fixing portion by freely adjusting the angle and interval. 手術台の側方に付設されるレールに脛骨側部材及び大腿骨側部材をスライド可能に取り付けるとともに、脛骨側部材及び大腿骨側部材に各ヒンジ・スライド機構のそれぞれベース部を連結した請求項1の手術ロボット用下肢把持治具。   The tibial side member and the femoral side member are slidably attached to a rail attached to the side of the operating table, and the base portions of the hinge / sliding mechanisms are connected to the tibial side member and the femoral side member, respectively. Lower limb gripping jig for surgical robots. 脛骨側固定部と脛骨の間及び大腿骨側固定部と大腿骨の間に流体の流入出によって膨張、収縮する袋を介在させた請求項1又は2の手術ロボット用下肢把持治具。   The lower limb grasping jig for a surgical robot according to claim 1 or 2, wherein a bag that is inflated and contracted by fluid inflow and outflow is interposed between the tibial side fixing portion and the tibia and between the femoral side fixing portion and the femur. 請求項1〜3いずれかの手術ロボット用下肢把持治具がX線高透過材料で構成される手術ロボット用下肢把持治具。   A lower limb gripping jig for a surgical robot, wherein the lower limb gripping jig for a surgical robot according to any one of claims 1 to 3 is made of an X-ray highly transparent material.
JP2006028259A 2006-02-06 2006-02-06 Leg holding tool for surgery robot Pending JP2007202950A (en)

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US11135021B2 (en) 2016-06-16 2021-10-05 Zimmer, Inc. Soft tissue balancing in articular surgery
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US11707333B2 (en) 2016-06-16 2023-07-25 Zimmer, Inc. Soft tissue balancing in articular surgery
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