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1.
文章给出了一种基于核磁共振技术的三维阻抗成像(电导率分布)重构算法,并将该方法应用于人体头部组织电导率分布重构上。该代数重构方法是利用高分辨率的核磁共振成像系统对成像物体进行三维构建和不同组织的边界区分,根据核磁共振系统中测量得到的磁感应强度Bx和By分量并结合有限元数值计算得到的电流密度分布J组成非线性矩阵,通过迭代求解此非线性矩阵,来解决三维电导率分布的重构问题。在三层球头模型(包括头皮、颅骨和大脑)上分别进行的仿真实验结果表明,该算法具有较强的抗噪声能力和较好的收敛性,重构的头部电导率分布图像具有较高的精确性。  相似文献   

2.
科学可视化是指运用计算机图形学和图像处理技术,将科学计算过程中或者是计算结果的数据转换为图形或图像,在屏幕上显示出来并进行交互式处理的理论技术或方法。介绍了用反卷积荧光显微成像技术获得活体大鼠胰腺B细胞三维图像及对其进行科学可视化的主要过程和两种常用可视化算法,并运用这两种方法对所得到的三维图像进行处理以分析和研究细胞内分泌囊泡的空间分布。结果显示,当仅观察细胞三维图像的二维切片时,三维图像中的某些重要信息会被忽略,而使用科学可视化方法则可以从三维角度直观观察活体细胞内分泌囊泡的空间分布,并且可以观察到分泌囊泡的释放趋势和整体分布,从而为细胞生物学研究提供重要的信息。  相似文献   

3.
以行人的视觉直观感受为出发点, 以匈牙利塞克什白堡为研究区, 基于街景数据, 深入研究植被信息提取方法, 针对传统像素级分类容易造成过度提取的现象, 提出一种面向对象的街景图像分类方法, 构建了基于街景数据的绿视率模型, 并分析总结了街景图像拍摄时的水平视角、垂直视角、水平方向范围等镜头参数对绿视率计算的影响。研究结果表明: 面向对象的分类方法提升了街景图像分类的精度和效率, 为绿视率计算模型提供了新的数据源和计算方法; 采集街景图像时, 增加水平视角和垂直视角、扩大水平方向范围能使绿视率计算结果更加真实地反映行人视觉感受。构建的绿视率计算模型能从行人角度为街道绿化的布局和空间结构优化提供依据, 可为城市绿地规划设计、居住区视觉生态设计等提供参考依据。  相似文献   

4.
中国数字化辐射虚拟人研究是以中国数字人高分辨三维结构数据集为基础,构建可用于蒙特卡洛辐射模拟的三维计算模型,并实现X射线、中子、质子等多粒子多能级的仿真计算。论著中讨论了基于高分辨人体结构数据集的辐射模型构建过程和特点,以及蒙特卡洛模拟软件,并将剂量测定结果与现有的国外人体模型模拟数据进行了比较。中国数字化辐射虚拟人模型是具备中国人体特征的辐射模型。计算结果很大程度上补充或校正了现有放射学计量数据集,为临床放疗规划、核医药、核辐射防护设计提供精确量化参考。  相似文献   

5.
贝叶斯支端定年法是近些年开发的推断类群分异时间和演化速率的方法。它克服了传统分步计算的缺陷,但涉及的统计学知识也更多。本文从贝叶斯统计计算的角度分层剖析了支端定年法的原理和计算过程,按照分异时间的先验分布、演化速率的先验分布、特征状态变化的模型和马氏链蒙特卡罗算法几个部分,叙述并讨论了定年计算中的主要模型和算法。旨在一定程度上为古生物学家分析实际数据提供参考。  相似文献   

6.
将新型等效源法引入脑电场电位的计算,视激励源为偶极子,实现真实电源既可以在真实的头模型中产生电位,也可以在均质无界空间中产生电位.从无界空间中三维拉普拉斯方程解的球形等效源的有限级数项表达式可见,该半解析方法克服了头模型对电位分布的干扰,在无界空间中计算出的电位是电源的裸表现.本文利用等效分布源理论推导出无界空间中任意偶极子源的球形等效源的正演理论公式,为高分辨脑电地形图技术中的重构皮层电位提供了一种方法.  相似文献   

7.
人体骨骼肌肉层对心电传导和体表电位标测的影响   总被引:1,自引:1,他引:0       下载免费PDF全文
应用电磁场数值计算方法求解三维心电图正问题,重点考察了人体骨骼肌肉层的各向异性导电性对心电传导的影响。推导了描述人类心电场的有限元模型和边界元模型,以及二者结合的形式,并在一个包含异性导电肌肉层的三维人体模下进行了模拟计算。  相似文献   

8.
目的分析放疗科设备之间信息的整合。材料与方法通过对DICOM RT(Radiotherapy in DICOM)标准的了解,利用Pinnacle放射治疗计划系统(Treatment Planning System,TPS)、PrecisePLAN放射治疗计划系统和Eclipse放射治疗计划系统对某一选定病人进行轮廓勾画和剂量计算。然后,把轮廓勾画好的病人信息及计算完毕的病人信息分别在这三台TPS之间进行相互传递,并比较传递前后病人信息的差异。结果1)大孔径CT得到的CT图像可以传递给TPS;2)Pinnacle TPS的数据信息可以传递给PrecisePLAN TPS和Eclipse TPS,但是存在轮廓缺陷;3)PrecisePLAN TPS和Eclipse TPs之间不能互相传递数据,也不能把数据信息传递给Pinnacle TPS;4)三台TPS都不能把病人的治疗计划传递给另外的TPS。结论在当前三家国外生产加速器的大公司并存及国内生产加速器的企业落后的情况下,医院设备主管部门应当考虑购买兼容性较好的设备或者购买同一家公司的放射治疗设备。  相似文献   

9.
目的:探索建立一种新的自动识别标志点的方法.方法:本方法主要分成三步:首先,根据标志点的灰度特征在3D图像上搜索标志点,并得到候选点;然后,计算出搜索到的候选点区域的亮度重心,并作为该点的位置坐标;最后,根据标志点大小、相互间位置关系以及标志点周围区域像素的灰度变化等特征,筛选出真正的标志点.结果:利用该算法对三维理想模型和真实CT重建模型上的标志点进行识别,实验的结果表明该算法能准确识别出这两种模型上的标志点,平均误差均小于2个象素.结论:该方法能快速准确地识别出3D医学图像中的标志点,它不需要人为干预,且不受标志点形状的影响.  相似文献   

10.
目的:冠状动脉粥样硬化好发于具有特殊几何构型的血管部位,提示血流动力学参数在粥样硬化形成方面起到重要作用.以往研究多局限于理想的血管模型,本文旨在探索以CT图像为基础构建个体化冠状动脉血流动力学模型的技术方法,对人体左冠状动脉前降支粥样硬化病变狭窄处进行计算流体动力学(computational fluid dynamics,CFD)数值模拟,探讨冠状动脉粥样硬化病变形成和发展的血流动力学机制.方法:用MIMICS软件读取CTA数据,以CT图像为基础进行冠状动脉三维几何建模,假设动脉血流为层流、不可压缩、牛顿流体,入口血液流速随时间周期性变化,应用有限体积法FLUENT软件进行血流数值模拟,分析与动脉粥样硬化形成、发展相关的血流动力学参数.结果:获得个体化左冠状动脉前降支狭窄处血管模型及血流动力学参数,数值模拟结果包括冠状动脉的血液流场、壁面压力(wall pressure WP)及壁面切应力(wall shear stress WSS)分布,可见狭窄段血管血液流速加快,WP降低、WSS增高,且在狭窄邻近区域出现低WSS区、较高的WP及血液湍流区域.结论:以CT图像为基础的CFD技术是在体评价人狭窄冠状动脉内血流动力学状况与冠状动脉粥样硬化病变之间关系的有效方法,能够更为真实的建立人体血管几何模型,为分析血流动力学参数与冠状动脉粥样硬化形成与发展的关系提供研究手段.  相似文献   

11.
Radiation therapy is an established method of cancer treatment. New technologies in cancer radiotherapy need a more accurate computation of the dose delivered in the radiotherapy treatment plan. This study presents some results of a Geant4-based application for simulation of the absorbed dose distribution given by a medical linear accelerator (LINAC). The LINAC geometry is accurately described in the Monte Carlo code with use of the accelerator manufacturer''s specifications. The capability of the software for evaluating the dose distribution has been verified by comparisons with measurements in a water phantom; the comparisons were performed for percentage depth dose (PDD) and profiles for various field sizes and depths, for a 6-MV electron beam. Experimental and calculated dose values were in good agreement both in PDD and in transverse sections of the water phantom.  相似文献   

12.
PurposeThis work compares Monte Carlo dose calculations performed using the RayStation treatment planning system against data measured on a Varian Truebeam linear accelerator with 6 MV and 10 MV FFF photon beams.MethodsThe dosimetric performance of the RayStation Monte Carlo calculations was evaluated in a variety of irradiation geometries employing homogeneous and heterogeneous phantoms. Profile and depth dose comparisons against measurement were carried out in relative mode using the gamma index as a quantitative measure of similarity within the central high dose regions.ResultsThe results demonstrate that the treatment planning system dose calculation engine agrees with measurement to within 2%/1 mm for more than 95% of the data points in the high dose regions for all test cases. A systematic underestimation was observed at the tail of the profile penumbra and out of field, with mean differences generally <0.5 mm or 1% of curve dose maximum respectively. Out of field agreement varied between evaluated beam models.ConclusionsThe RayStation implementation of photon Monte Carlo dose calculations show good agreement with measured data for the range of scenarios considered in this work and is deemed sufficiently accurate for introduction into clinical use.  相似文献   

13.
Dental prostheses made of high density material contribute to modify dose distribution in head and neck cancer treatment. Our objective is to quantify dose perturbation due to high density inhomogeneity with experimental measurements and Monte Carlo simulations.Firstly, measurements were carried in a phantom representing a human jaw with thermoluminescent detectors (GR200A) and EBT2 Gafchromic films in the vicinity of three samples: a healthy tooth, a tooth with amalgam and a Ni–Cr crown, irradiated in clinical configuration. Secondly, Monte Carlo simulations (BEAMnrc code) were assessed in an identical configuration.Experimental measurements and simulation results confirm the two well-known phenomena: firstly the passage from a low density medium to a high density medium induces backscattered electrons causing a dose increase at the interface, and secondly, the passage from a high density medium to a low density medium creates a dose decrease near the interface. So, the results show a 1.4% and 23.8% backscatter dose rise and attenuation after sample of 26.7% and 10.9% respectively for tooth with amalgam and crown compared to the healthy tooth.Although a tooth with amalgam has a density of about 12–13, the changes generated are not significant. However, the results for crown (density of 8) are very significant and the discordance observed may be due to calculation point size difference 0.8 mm and 0.25 mm respectively for TLD and Monte Carlo. The use of Monte Carlo simulations and experimental measurements provides objective evidence to evaluate treatment planning system results with metal dental prostheses.  相似文献   

14.
Organ or tissue equivalent dose, the most important quantity in radiation protection, cannot be measured directly. Therefore it became common practice to calculate the quantity of interest with Monte Carlo methods applied to so-called human phantoms, which are virtual representations of the human body. The Monte Carlo computer code determines conversion coefficients, which are ratios between organ or tissue equivalent dose and measurable quantities. Conversion coefficients have been published by the ICRP (Report No. 74) for various types of radiation, energies and fields, which have been calculated, among others, with the mathematical phantoms ADAM and EVA. Since then progress of image processing, and of clock speed and memory capacity of computers made it possible to create so-called voxel phantoms, which are a far more realistic representation of the human body. Voxel (Volume pixel) phantoms are built from segmented CT and/or MRI images of real persons. A complete set of such images can be joined to a 3-dimensional representation of the human body, which can be linked to a Monte Carlo code allowing for particle transport calculations. A modified version of the VOX_TISS8 human voxel phantom (Yale University) has been connected to the EGS4 Monte Carlo code. The paper explains the modifications, which have been made, the method of coupling the voxel phantom with the code, and presents results as conversion coefficients between organ equivalent dose and kerma in air for external photon radiation. A comparison of the results with published data shows good agreement.  相似文献   

15.
An increasing number of studies have shown that post-mastectomy radiotherapy presents benefits associated with the patients survival and a significant fraction of the treated patients makes use of tissue expanders for breast reconstruction. Some models of tissue expanders have a magnetic disk on their surface that constitutes heterogeneity in the radiation field, which can affect the dose distribution during the radiotherapy treatment. In this study, the influence of a metallic heterogeneity positioned in a breast tissue expander was evaluated by means of Monte Carlo simulations using the MCNPX code and using Eclipse treatment planning system. Deposited energy values were calculated in structures which have clinical importance for the treatment. Additionally, the effect in the absorbed energy due to backscattering and attenuation of the incident beam caused by the heterogeneity, as well as due to the expansion of the prosthesis, was evaluated in target structures for a 6 MV photon beam by simulations. The dose distributions for a breast treatment were calculated using a convolution/superposition algorithm from the Eclipse treatment planning system. When compared with the smallest breast expander volume, underdosage of 7% was found for the largest volume of breast implant, in the case of frontal irradiation of the chest wall, by Monte Carlo simulations. No significant changes were found in dose distributions for the presence of the heterogeneity during the treatment planning of irradiation with an opposed pair of beams. Even considering the limitation of the treatment planning system, the results obtained with its use confirm those ones found by Monte Carlo simulations for a tangent beam irradiation. The presence of a heterogeneity didńt alters the dose distributions on treatment structures. The underdosage of 7% observed with Monte Carlo simulations were found for irradiation at 0°, not used frequently in a clinical routine.  相似文献   

16.
BackgroundTo the present date, IORT has been eye and hand guided without treatment planning and tissue heterogeneity correction. This limits the precision of the application and the precise documentation of the location and the deposited dose in the tissue. Here we present a set-up where we use image guidance by intraoperative cone beam computed tomography (CBCT) for precise online Monte Carlo treatment planning including tissue heterogeneity correction.Materials and methodsAn IORT was performed during balloon kyphoplasty using a dedicated Needle Applicator. An intraoperative CBCT was registered with a pre-op CT. Treatment planning was performed in Radiance using a hybrid Monte Carlo algorithm simulating dose in homogeneous (MCwater) and heterogeneous medium (MChet). Dose distributions on CBCT and pre-op CT were compared with each other. Spinal cord and the metastasis doses were evaluated.ResultsThe MCwater calculations showed a spherical dose distribution as expected. The minimum target dose for the MChet simulations on pre-op CT was increased by 40% while the maximum spinal cord dose was decreased by 35%. Due to the artefacts on the CBCT the comparison between MChet simulations on CBCT and pre-op CT showed differences up to 50% in dose.ConclusionsigIORT and online treatment planning improves the accuracy of IORT. However, the current set-up is limited by CT artefacts. Fusing an intraoperative CBCT with a pre-op CT allows the combination of an accurate dose calculation with the knowledge of the correct source/applicator position. This method can be also used for pre-operative treatment planning followed by image guided surgery.  相似文献   

17.
The aim of this study was to describe a detailed instruction of intensity modulated radiotherapy (IMRT) planning simulation using BEAMnrc-DOSXYZnrc code system (EGSnrc package) and present a new graphical user interface based on MATLAB code (The MathWorks) to combine more than one. 3ddose file which were obtained from the IMRT plan.This study was performed in four phases: the commissioning of Varian Clinac iX6 MV, the simulation of IMRT planning in EGSnrc, the creation of in-house VDOSE GUI, and the analysis of the isodose contour and dose volume histogram (DVH) curve from several beam angles. The plan paramaters in sequence and control point files were extracted from the planning data in Tan Tock Seng Hospital Singapore (multileaf collimator (MLC) leaf positions – bank A and bank B, gantry angles, coordinate of isocenters, and MU indexes).VDOSE GUI which was created in this study can display the distribution dose curve in each slice and beam angle. Dose distributions from various MLC settings and beam angles yield different dose distributions even though they used the same number of simulated particles. This was due to the differences in the MLC leaf openings in every field. The value of the relative dose error between the two dose ditributions for “body” was 51.23 %. The Monte Carlo (MC) data was normalized with the maximum dose but the analytical anisotropic algorithm (AAA) data was normalized by the dose in the isocenter.In this study, we have presented a Monte Carlo simulation framework for IMRT dose calculation using DOSXYZnrc source 21. Further studies are needed in conducting IMRT simulations using EGSnrc to minimize the different dose error and dose volume histogram deviation.  相似文献   

18.
A new deterministic method for calculating the dose distribution in the electron radiotherapy field is presented. The aim of this work was to validate our model by comparing it with the Monte Carlo simulation toolkit, GEANT4. A comparison of the longitudinal and transverse dose deposition profiles and electron distributions in homogeneous water phantoms showed a good accuracy of our model for electron transport, while reducing the calculation time by a factor of 50. Although the Bremsstrahlung effect is not yet implemented in our model, we propose here a method that solves the Boltzmann kinetic equation and provides a viable and efficient alternative to the expensive Monte Carlo modeling.  相似文献   

19.
20.
AimThe aim of this work was to develop multiple-source models for electron beams of the NEPTUN 10PC medical linear accelerator using the BEAMDP computer code.BackgroundOne of the most accurate techniques of radiotherapy dose calculation is the Monte Carlo (MC) simulation of radiation transport, which requires detailed information of the beam in the form of a phase-space file. The computing time required to simulate the beam data and obtain phase-space files from a clinical accelerator is significant. Calculation of dose distributions using multiple-source models is an alternative method to phase-space data as direct input to the dose calculation system.Materials and methodsMonte Carlo simulation of accelerator head was done in which a record was kept of the particle phase-space regarding the details of the particle history. Multiple-source models were built from the phase-space files of Monte Carlo simulations. These simplified beam models were used to generate Monte Carlo dose calculations and to compare those calculations with phase-space data for electron beams.ResultsComparison of the measured and calculated dose distributions using the phase-space files and multiple-source models for three electron beam energies showed that the measured and calculated values match well each other throughout the curves.ConclusionIt was found that dose distributions calculated using both the multiple-source models and the phase-space data agree within 1.3%, demonstrating that the models can be used for dosimetry research purposes and dose calculations in radiotherapy.  相似文献   

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