CN205054432U - General mark structure of operation navigation - Google Patents

Abstract

The utility model discloses a general mark structure of operation navigation, include: base, ball cap and the club body, the base is formed by integrative forming technology manufacturing, ball cap surface and base hemispheroid surface all scribble the reflector layer, and the hollow hemispheroid of ball cap and base coordinates through interior external screw thread, mark structure base and ball cap all form by having the material producing who is higher than skin CT value, can be by the CT imaging device scanning imagery, the club body is placed in the base, the internal packing of club has solution, scanning imagery under MRI imaging device, the club body twist move the ball cap after, can place to the mark structure and inside or take out, it is trailed discernment by optics navigation to scribble the ball cap of reflector layer and the hollow hemispheroid of base. Have the artifical positioning error who has reduced the mark structure, improved operation navigation's advantages such as navigation accuracy.

Description

Translated fromChinese

一种手术导航通用标记结构A General Marking Structure for Surgical Navigation

技术领域technical field

本实用新型涉及计算机辅助手术导航研究领域，具体是一种手术导航通用标记结构。The utility model relates to the research field of computer-aided surgical navigation, in particular to a general marking structure for surgical navigation.

背景技术Background technique

手术导航技术近年来得到了快速的发展，逐渐用于神经外科、口腔颌面外科、骨科等手术中。手术导航技术是将三维空间定位技术、医学图像重建可视化和临床手术结合，使用定位仪器对手术器械和病人进行实时跟踪定位，通过坐标系变换，将手术器械在病人的人体结构三维重建空间中实时显示，以辅助医生完成高精度的手术规划和手术操作。手术导航的注册过程是手术导航中关键的一个步骤，手术注册通常采用基于标记结构的注册方法。当前临床上常用的手术导航系统主要使用基于光学的手术导航技术，手术注册时，使用一个安装有三个以上反光球的注册器，通过注册器的尖端点取多个粘贴在病人身上的标记结构中心或解剖标记结构，同时在病人三维重建图像中的对应位置手动获取这些标记结构在图像空间的坐标，然后进行病人注册。Surgical navigation technology has developed rapidly in recent years and is gradually used in neurosurgery, oral and maxillofacial surgery, orthopedics and other operations. Surgical navigation technology is a combination of three-dimensional space positioning technology, medical image reconstruction visualization and clinical surgery, using positioning instruments to track and locate surgical instruments and patients in real time, and through coordinate system transformation, the surgical instruments are real-time in the three-dimensional reconstruction space of the patient's human body structure. Display, to assist doctors to complete high-precision surgical planning and surgical operations. The registration process of surgical navigation is a key step in surgical navigation, and surgical registration usually adopts a registration method based on a marker structure. The current surgical navigation system commonly used in clinical practice mainly uses optical-based surgical navigation technology. During surgical registration, a registration device equipped with more than three reflective balls is used, and the center of multiple marking structures pasted on the patient is taken through the tip of the registration device. Or anatomical marker structures, and at the same time manually obtain the coordinates of these marker structures in the image space at the corresponding positions in the patient's 3D reconstruction image, and then perform patient registration.

手术导航的导航精度受标记结构注册精度、定位系统和手术工具设计制造精度等因素的影响。其中注册精度是影响手术导航精度的一个主要因素。当前临床上通用的手动定位标记结构注册方法受人工操作的个体差异性影响，难以控制最终的注册精度，通常为了获取满足手术需求的导航精度，需要耗费较长的时间进行多次标记结构定位和注册，大大延长了手术的时间，增加了医生的负担和手术风险，同时也降低了手术的效率。自动获取标记结构坐标是解决手工获取标记结构坐标的一种可行方法，但现在的临床上使用的粘贴标记结构和解剖标记结构难以实现自动定位。另外，对于不同的成像设备，由于其成像原理不同，能够被一种成像设备识别的标记结构却不能为另外一种成像设备所识别，因而需要为每种成像设备定制标记结构，导致标记结构种类繁多，为临床上的使用带来不便。The navigation accuracy of surgical navigation is affected by factors such as the registration accuracy of marker structures, the positioning system, and the design and manufacturing accuracy of surgical tools. Among them, registration accuracy is a main factor affecting the accuracy of surgical navigation. The current general clinical manual positioning marker structure registration method is affected by individual differences in manual operations, and it is difficult to control the final registration accuracy. Usually, in order to obtain the navigation accuracy that meets the surgical needs, it takes a long time to perform multiple marker structure positioning and positioning. Registration greatly prolongs the time of surgery, increases the burden on doctors and the risk of surgery, and also reduces the efficiency of surgery. Automatically obtaining the coordinates of the marker structure is a feasible method to solve the problem of manual acquisition of the coordinates of the marker structure, but it is difficult to realize the automatic positioning of the pasted marker structure and anatomical marker structure used in clinical practice. In addition, for different imaging devices, due to their different imaging principles, the marking structure that can be recognized by one imaging device cannot be recognized by another imaging device, so it is necessary to customize the marking structure for each imaging device, resulting in the type of marking structure Various, bring inconvenience to clinical use.

为了解决当前标记结构定位存在的问题，本实用新型设计一种的手术导航通用标记结构，能够在图像空间和实际空间进行自动定位，从而消除手动定位的个体差异性，提高了手术注册的精度。In order to solve the problems existing in the positioning of the current marking structure, the utility model designs a general marking structure for surgical navigation, which can perform automatic positioning in the image space and the actual space, thereby eliminating individual differences in manual positioning and improving the accuracy of surgical registration.

实用新型内容Utility model content

本实用新型的首要目的在于克服现有技术的缺点与不足，提供一种手术导航通用标记结构，该手术导航通用标记结构是基于标记结构的制作材料和标记结构的几何结构，实现了自动获取标记结构的图像空间位置。The primary purpose of the utility model is to overcome the shortcomings and deficiencies of the prior art, and provide a general marking structure for surgical navigation. The general marking structure for surgical navigation is based on the manufacturing materials of the marking structure and the geometric structure of the marking structure, and realizes automatic acquisition of markings. The image space location of the structure.

本实用新型的另一目的在于克服现有技术的缺点与不足，提供一种获取所述的手术导航通用标记结构的图像位置获取方法，该图像位置获取方法是一种用于手术导航，并同时用于CT和MRI成像设备的图像位置获取方法。Another purpose of the present utility model is to overcome the shortcomings and deficiencies of the prior art, and provide a method for obtaining the image position of the general marking structure for surgical navigation. The method for obtaining the image position is a method for surgical navigation, and simultaneously Image location acquisition methods for CT and MRI imaging equipment.

本实用新型的首要目的通过以下的技术方案实现：一种手术导航通用标记结构，该标记结构能够被CT/MRI设备扫描成像，并且能够使用定位算法进行自动定位，主要包括：基座、球帽和球杆体，所述基座具有依次连接的空心半球体和圆柱体底座；所述球杆体放置于基座内；所述球帽下部的内侧具有内螺纹；所述基座上部的外侧具有外螺纹；所述内螺纹和外螺纹是相互配合的。The primary purpose of the utility model is achieved through the following technical solutions: a general marking structure for surgical navigation, which can be scanned and imaged by CT/MRI equipment, and can be automatically positioned using a positioning algorithm, mainly including: a base, a ball cap And the club body, the base has a hollow hemisphere and a cylindrical base connected in sequence; the club body is placed in the base; the inner side of the lower part of the ball cap has internal threads; the outer side of the upper part of the base It has an external thread; the internal thread and the external thread cooperate with each other.

所述的基座和球帽都由具有高于皮肤CT值的材料制作而成，所述的基座和球帽都被CT成像设备扫描成像。Both the base and the ball cap are made of materials with a CT value higher than that of the skin, and both the base and the ball cap are scanned and imaged by CT imaging equipment.

所述球杆体内填充有溶液，所述溶液被MRI成像设备扫描成像。The club body is filled with a solution, and the solution is scanned and imaged by an MRI imaging device.

所述球帽外表面和基座的空心球体外表面都涂有反射近红外光的反光涂层，所述反光涂层被光学导航系统识别跟踪，所述近红外光的反光涂层是现有技术常用的反光涂层。Both the outer surface of the ball cap and the outer surface of the hollow sphere of the base are coated with a reflective coating that reflects near-infrared light, and the reflective coating is identified and tracked by an optical navigation system. The reflective coating for near-infrared light is an existing Technology commonly used reflective coating.

所述球帽为空心的半球体。The ball cap is a hollow hemisphere.

本实用新型的另一目的通过以下技术方案实现：一种获取所述的手术导航通用标记结构的图像位置获取方法，所述标记结构图像位置获取方法为自动获取标记结构球帽中心、基座中心及其对称轴，主要包括如下步骤：Another object of the present utility model is achieved through the following technical solutions: a method for obtaining the image position of the general marking structure for surgical navigation, the method for obtaining the image position of the marking structure is to automatically obtain the center of the ball cap and the center of the base of the marking structure and its axis of symmetry, mainly including the following steps:

1)将所述手术导航通用标记结构放置在需定位区域，获取CT或MRI设备扫描的图像序列，所述基座和球帽在CT设备下扫描成像，填充在所述球杆体内的溶液在MRI设备中扫描成像，然后对CT或MRI图像进行三维重建，形成三维重建模型；1) Place the general marker structure for surgical navigation in the area to be positioned, and obtain an image sequence scanned by CT or MRI equipment. The base and the ball cap are scanned and imaged under the CT equipment, and the solution filled in the club body is Scan imaging in MRI equipment, and then perform three-dimensional reconstruction on CT or MRI images to form a three-dimensional reconstruction model;

2)对步骤1)的三维重建模型进行滤波去噪，然后根据设定的阈值分割滤波去噪后的三维重建模型；2) Filter and denoise the 3D reconstruction model in step 1), and then segment the 3D reconstruction model after filtering and denoising according to the set threshold;

3)计算步骤2)分割得到的每个连续子区域的体积，作为候选子区域，与标记结构的CAD模型体积进行比较，根据设置的阈值范围进行初步的筛选；3) The volume of each continuous sub-region obtained by the calculation step 2) is compared with the CAD model volume of the marked structure as a candidate sub-region, and preliminary screening is carried out according to the threshold range set;

4)计算步骤3)筛选后得到的候选子区域的最长主轴，计算子区域的关于最长主轴的对称性，进行第二次的标记结构筛选；4) Calculate the longest main axis of the candidate sub-region obtained after the screening in step 3), calculate the symmetry of the sub-region about the longest main axis, and perform the second marker structure screening;

5)使用主成分分析法计算步骤4)得到的候选子区域的三个相互正交的主轴，并计算候选子区域在三个相互正交的主轴上的投影范围，同时计算出标记结构CAD模型的主轴及标记结构CAD模型在三个相互正交的主轴上的投影范围，将候选子区域与标记结构CAD模型在三个相互正交的主轴上的投影范围进行比较，满足所设定阈值的子区域即为自动搜索找到的标记结构三维重建模型，并计算出每个标记结构的球帽中心和基座中心。5) Calculate the three mutually orthogonal main axes of the candidate sub-region obtained in step 4) by using the principal component analysis method, and calculate the projection range of the candidate sub-region on the three mutually orthogonal main axes, and calculate the CAD model of the marked structure at the same time The main axis and the projection range of the marked structure CAD model on the three mutually orthogonal main axes, the candidate sub-region is compared with the projected range of the marked structure CAD model on the three mutually orthogonal main axes, and the set threshold is satisfied. The sub-region is the 3D reconstruction model of the marked structure found by the automatic search, and the center of the spherical cap and the center of the base of each marked structure are calculated.

本实用新型由于采取以上技术方案，其具有以下优点：The utility model has the following advantages due to the adoption of the above technical scheme:

1、本实用新型由于采用特殊设计的标记结构，既可以被MRI扫描成像，也可以被CT扫描成像，无论是MRI图像还是CT图像，通过简单地图像处理可以将标记结构与人体的皮肤及其他组织区分开来，从而本实用新型中涉及到的标记结构可以同时适用于MRI和CT两种成像设备；1. Because the utility model adopts a specially designed marking structure, it can be imaged by MRI scanning or CT scanning. Whether it is an MRI image or a CT image, the marking structure can be combined with the skin of the human body and other areas through simple image processing. Tissues are distinguished, so that the marking structure involved in the utility model can be applied to both MRI and CT imaging equipment;

2、本实用新型设计的通用标记结构的球帽的反光涂层能够为光学导航系统识别跟踪，而在图像空间，本实用新型设计的图像位置获取方法基于标记结构的几何特征能够对标记结构的球帽中心进行准确地定位，通过图像灰度值的高对比度及标记结构的形状对其进行精确地自动定位，降低了标记结构的人工定位误差，提高了手术导航系统的导航精度。2. The reflective coating of the ball cap of the general marking structure designed by the utility model can be used for the identification and tracking of the optical navigation system, and in the image space, the image position acquisition method designed by the utility model can be based on the geometric characteristics of the marking structure. The center of the ball cap is accurately positioned, and the high contrast of the gray value of the image and the shape of the marked structure are used to accurately and automatically position it, which reduces the manual positioning error of the marked structure and improves the navigation accuracy of the surgical navigation system.

3、本实用新型设计的标记结构能够方便地使用医用双面胶粘贴在人体皮肤表面，方便粘贴和摘除且对病人无伤害。本实用新型为可以用于使用不同医学成像设备的光学手术导航系统皮肤粘贴标记结构。3. The marking structure designed by the utility model can be conveniently pasted on the surface of human skin by using medical double-sided adhesive tape, which is convenient for pasting and removal and has no harm to the patient. The utility model is a skin sticking mark structure that can be used for an optical surgery navigation system using different medical imaging equipment.

附图说明Description of drawings

图1a为手术导航通用标记结构的实施例1的爆炸图。Fig. 1a is an exploded view of Embodiment 1 of a general marker structure for surgical navigation.

图1b为手术导航通用标记结构的实施例2的爆炸图。Fig. 1b is an exploded view of Embodiment 2 of the universal marker structure for surgical navigation.

图2a为手术导航通用标记结构的左视图。Figure 2a is a left side view of the general marker structure for surgical navigation.

图2b为手术导航通用标记结构的剖面图。Fig. 2b is a cross-sectional view of a general marker structure for surgical navigation.

图2c为手术导航通用标记结构的基座与球帽结合处的局部放大图。Fig. 2c is a partially enlarged view of the junction of the base and the ball cap of the general marker structure for surgical navigation.

图中，10表示基座，11表示基座上部的外螺纹，20表示球杆体，30表示球帽，31表示球帽下部的内螺纹。In the figure, 10 represents the base, 11 represents the external thread on the top of the base, 20 represents the club body, 30 represents the ball cap, and 31 represents the internal thread on the bottom of the ball cap.

具体实施方式detailed description

为便于说明本实用新型于上述实用新型内容一栏中所表示的中心思想，兹以具体实施例表达。实施例中各种不同物件是按适于说明的比例、尺寸而描绘，而非按实际元件的比例予以绘制，事先叙明。且以下的说明中，类似的元件是以相同的编号来表示。请参阅图1和图2，本实用新型一种手术导航通用标记结构，包括：基座10、球杆体20、球帽30。各部件的组合及位置关系，详述如下：In order to illustrate the central idea of the utility model in the column of the above-mentioned utility model content, it is expressed in specific embodiments. Various objects in the embodiments are drawn according to proportions and sizes suitable for illustration, rather than drawn according to the proportion of actual components, which is stated in advance. And in the following description, similar components are denoted by the same numerals. Please refer to FIG. 1 and FIG. 2 , a general marking structure for surgical navigation of the present invention, including: a base 10 , a club body 20 , and a ball cap 30 . The combination and positional relationship of each component are described in detail as follows:

实施例1Example 1

如图1a所示，基座10具有依次连接的空心半球体和圆柱体底座，所述基座10由一体成形制造工艺制造而成；球杆体20能够放置到基座上；基座10的圆柱体底座的下部实心圆柱体半径8mm，高为8mm；基座10的圆柱体底座的上部空心圆柱体外半径为2.5mm，内半径为1mm，高为6mm；球帽30外半径为6mm，内半径为5mm，球帽30和基座10通过外螺纹31和内螺纹11进行配合，球帽30外表面和基座10空心半球体外表面涂有一层反光层，具有较强反射近红外光的特性，能反射近红外光而为光学导航系统所识别跟踪。基座10与球帽30都由具有高于皮肤CT值的材料制作而成，能够被CT成像设备扫描成像，且没有伪影。如图2a、图2b和图2c所示，球杆体20的球体半径为5mm，圆柱杆体半径为1mm，高为5.4mm；球杆体20内部填充溶液，所填充的溶液在MRI成像设备下扫描成像。球杆体20在拧开球帽30后能够放置到标记结构的基座10上，拧上球帽30后便能将球杆体20固定在标记结构内部。As shown in Figure 1a, the base 10 has a hollow hemisphere and a cylindrical base connected in sequence, and the base 10 is manufactured by an integral forming manufacturing process; the club body 20 can be placed on the base; the base 10 The bottom solid cylinder of the cylinder base has a radius of 8mm and a height of 8mm; the outer radius of the upper hollow cylinder of the cylinder base of the base 10 is 2.5mm, the inner radius is 1mm, and the height is 6mm; the outer radius of the spherical cap 30 is 6mm, and the inner The radius is 5mm, the ball cap 30 and the base 10 are matched through the external thread 31 and the internal thread 11, and the outer surface of the ball cap 30 and the outer surface of the hollow hemisphere of the base 10 are coated with a layer of reflective layer, which has the characteristics of strong reflection of near-infrared light , can reflect near-infrared light and be identified and tracked by the optical navigation system. Both the base 10 and the ball cap 30 are made of materials with a CT value higher than that of the skin, and can be scanned and imaged by a CT imaging device without artifacts. As shown in Fig. 2a, Fig. 2b and Fig. 2c, the sphere radius of the club body 20 is 5 mm, the radius of the cylindrical shaft body is 1 mm, and the height is 5.4 mm; the interior of the club body 20 is filled with a solution, and the filled solution is placed under the MRI imaging device scan imaging. The club body 20 can be placed on the base 10 of the marking structure after the ball cap 30 is unscrewed, and the club body 20 can be fixed inside the marking structure after the ball cap 30 is screwed on.

使用如下方法获取本实用新型标记结构在医学图像中的位置，包括以下步骤：Use the following method to obtain the position of the marker structure of the present invention in the medical image, including the following steps:

1)将所述手术导航通用标记结构放置在需定位区域，获取CT或MRI设备扫描的图像序列，所述基座10和球帽30在CT设备下扫描成像，填充在所述球杆体20内的溶液在MRI设备中扫描成像，然后对CT或MRI图像进行三维重建，形成三维重建模型；1) Place the general marker structure for surgical navigation in the area to be positioned, and obtain an image sequence scanned by CT or MRI equipment. The base 10 and the ball cap 30 are scanned and imaged under the CT equipment, and filled in the club body 20 The solution inside is scanned and imaged in MRI equipment, and then the CT or MRI images are reconstructed in three dimensions to form a three-dimensional reconstruction model;

2)将三维重建模型进行高斯滤波，然后根据设定的阈值对三维重建模型进行分割，得到i个连续子区域的集合{Q_i}₁；2) Gaussian filtering is performed on the 3D reconstruction model, and then the 3D reconstruction model is segmented according to a set threshold to obtain a set {Q_i }₁ of i continuous sub-regions;

3)计算{Q_i}₁中每个连续子区域的体积，并与标记结构的CAD模型体积M进行比较，根据预设的阈值T₁筛选出满足条件j个的子区域集合{Q_j}₂，作为候选的标记结构集合；3) Calculate the volume of each continuous sub-region in {Q_i }₁ , and compare it with the CAD model volume M of the marked structure, and filter out a set of sub-regions {Q_j } that meet the condition j according to the preset threshold T₁₂ , as a set of candidate tag structures;

4)计算{Q_j}₂中每个子区域的最长主轴计算这些子区域的关于主轴的对称性，根据预设的阈值T₂剔除那些不满足条件的子区域，得到包含k个子区域的集合{Q_k}₂；4) Calculate the longest principal axis of each subregion in {Q_j }₂ Calculate these subregions with respect to the main axis The symmetry of , according to the preset threshold T₂ , those sub-regions that do not meet the conditions are eliminated, and a set {Q_k }₂ containing k sub-regions is obtained;

5)使用主成分分析法计算{Q_k}₃中每个子区域的三个相互正交的主轴并计算它们在三个相互正交的主轴的投影范围[A_{k_min},A_{k_max}]、[B_{k_min},B_{k_max}]、[C_{k_min},C_{k_max}]，同时计算出标记结构CAD模型的三个相互正交的主轴及其在三个相互正交的主轴上的投影范围[A′_{k_min},A′_{k_max}]、[B′_{k_min},B′_{k_max}]、[C′_{k_min},C′_{k_max}]，将[A_{k_min},A_{k_max}]与[A′_{k_min},A′_{k_max}]、[B_{k_min},B_{k_max}]与[B′_{k_min},B′_{k_max}]、[C_{k_min},C_{k_max}]与[C′_{k_min},C′_{k_max}]的进行成对比较，满足预设阈值T₃的子区域集合{Q_d}₄即为最终自动搜索定位的标记结构三维重建模型，然后计算出每个标记结构的球帽30中心和基座10中心。5) Calculate the three mutually orthogonal principal axes for each subregion in {Q_k }₃ using principal component analysis And calculate their projection ranges [A_{k_min} , A_{k_max} ], [B_{k_min} , B_{k_max} ], [C_{k_min} , C_{k_max} ] on three mutually orthogonal main axes, and calculate three mutually orthogonal axis of intersection and its projection ranges [A′_{k_min} , A′_{k_max} ], [B′_{k_min} , B′_{k_max} ], [C′_{k_min} , C′_{k_max} ] on three mutually orthogonal principal axes. [A_{k_min} , A_{k_max} ] and [A′_{k_min} , A′_{k_max} ], [B_{k_min} , B_{k_max} ] and [B′_{k_min} , B′_{k_max} ], [C_{k_min} , C_{k_max} ] and [C′_{k_min} , C′_{k_max} ] Pairwise comparison, the set of subregions {Q_d }₄ satisfying the preset threshold T₃ is the final 3D reconstruction model of the marker structure automatically searched and located, and then the center of the ball cap 30 and the center of the base 10 of each marker structure are calculated.

实施例2Example 2

本实施例除以下内容以外，同实施例1：This embodiment is the same as Embodiment 1 except the following:

实施例2与实施例1的不同之处在于球杆体20的几何结构，如图1b所示：球杆体20为球体，球体半径为5mm；球杆体20能够放置到基座10上；球杆体20内部填充溶液，所填充的溶液在MRI成像设备下扫描成像。The difference between Embodiment 2 and Embodiment 1 lies in the geometric structure of the club body 20 , as shown in FIG. 1 b : the club body 20 is a sphere with a radius of 5 mm; the club body 20 can be placed on the base 10 ; The club body 20 is filled with a solution, and the filled solution is scanned and imaged under an MRI imaging device.

虽然本实用新型是以最佳实施例做说明，但本领域技术人员能在不脱离本实用新型精神与范畴下做各种不同形式的改变。以上所举实施例仅用以说明本实用新型而已，非用以限制本实用新型的权利要求保护范围。举凡不违本实用新型精神所做出的种种修改或变化，俱属本实用新型权利要求保护范围之内。Although the utility model is described with the best embodiment, those skilled in the art can make various changes without departing from the spirit and scope of the utility model. The above-mentioned embodiments are only used to illustrate the utility model, and are not intended to limit the protection scope of the claims of the utility model. All modifications or changes made without violating the spirit of the utility model are within the protection scope of the claims of the utility model.

Claims (3)

1. for a common tags structure for surgical navigational, it is characterized in that, comprise pedestal, ball cap and club body, described pedestal has the hollow hemisphere and cylinder base that connect successively, and described pedestal is formed by integrally formed manufacture technics; Described club body is positioned in pedestal, is filled with solution in described club body; The inner side of described ball cap bottom has female thread; The outside on described pedestal top has external screw thread; Described female thread and external screw thread cooperatively interact.

2. the common tags structure for surgical navigational according to claim 1, is characterized in that, the hollow ball outer surface of described ball cap outer surface and pedestal all scribbles the reflecting coating of reflect near infrared light.

3. the common tags structure for surgical navigational according to claim 1, it is characterized in that, described ball cap is hollow hemisphere, the interior diameter of the hollow hemisphere of described ball cap is equal with the interior diameter of the hollow hemisphere of pedestal, described cylinder base is hollow cylinder, described club body has interconnective hollow ball and cylinder, described hollow ball overall diameter is less than or equal to the hollow hemisphere interior diameter of pedestal, the cylinder overall diameter of described club body is less than or equal to the hollow cylinder interior diameter of pedestal, the cental axial position of the hollow hemisphere of described pedestal has hole, the diameter in described hole is more than or equal to the cylinder overall diameter of club body, the cylinder passing hole of described club body stretches in the hollow cylinder of pedestal.