Survey of Glyph-based Visualization Techniques for Spatial Multivariate Medical Data

Ropinski, Timo, Oeltze, Steffen, Preim, Bernhard

January 2011

In this survey article, we review glyph-based visualization techniques, which have been exploited when visualizing spatial multivariate medical data. To classify these techniques, we derive a taxonomy of glyph properties, which is based on classification concepts established in information visualization. By considering both the glyph visualization as well as the interaction techniques that are employed to generate or explore the glyph visualization, we are able to classify glyph techniques into two main groups: those supporting pre-attentive and those supporting attentive processing. With respect to this classification, we review glyph-based techniques described in the medical visualization literature. Based on the outcome of the literature review, we propose design guidelines for glyph visualizations in the medical domain.

Glyphs

medical visualization

multivariate data

Towards an Image-based Indicator for Peripheral Artery Disease Classification and Localization

Gillmann, Christina, Matsuura, John M., Hagen, Hans, Wischgoll, Thomas

25 January 2019

Peripheral Artery Disease (PAD) is an often occurring problem caused by narrowed veins. With this type of disease, mostly the legs receive an insufficient supply of blood to sustain their functions. This can result in an amputation of extremities or strokes. In order to quantify the risks, doctors consult a classification table which is based on the pain response of a patient. This classification is subjective and does not indicate the exact origin of the PAD symptoms. Resulting from this, complications can occur unprompted. We present the first results for an image-based indicator assisting medical doctors in estimating the stage of PAD and its location. Therefore, a segmentation tree is utilized to compare the changes in a healthy versus diseased leg. We provide a highlighting mechanism that allows users to review the location of changes in selected structures. To show the effectiveness of the presented approach, we demonstrate a localization of the PAD and show how the presented technique can be utilized for a novel image-based indicator of PAD stages.

info:eu-repo/classification/ddc/006

ddc:006

Visualization techniques for large-scale and complex volume date / 大規模・複雑ボリュームデータのための可視化技術

Kun, Zhao

25 May 2015

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19186号 / 工博第4063号 / 新制||工||1627(附属図書館) / 32178 / 京都大学大学院工学研究科電気工学専攻 / (主査)教授 小山田 耕二, 教授 小林 哲生, 教授 中村 裕一 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Large-scale Visualization

Volume Rendering

Compression

Time-varying

Multi-varita Visualization

Medical Visualization

Ocean Visualization

500

Visualization of Time-varying Scientific Data through Comparative Fusion and Temporal Behavior Analysis

Woodring, Jonathan Lee

01 September 2009

No description available.

Computer Science

scientific visualization

medical visualization

time-varying visualization

transfer functions

comparative visualization

animation

Simulation of Biological Tissue using Mass-Spring-Damper Models / Simulering av biologisk vävnad med hjälp av mass-spring-damper-modeller

Eriksson, Emil

January 2013

The goal of this project was to evaluate the viability of a mass-spring-damper based model for modeling of biological tissue. A method for automatically generating such a model from data taken from 3D medical imaging equipment including both the generation of point masses and an algorithm for generating the spring-damper links between these points is presented. Furthermore, an implementation of a simulation of this model running in real-time by utilizing the parallel computational power of modern GPU hardware through OpenCL is described. This implementation uses the fourth order Runge-Kutta method to improve stability over similar implementations. The difficulty of maintaining stability while still providing rigidness to the simulated tissue is thoroughly discussed. Several observations on the influence of the structure of the model on the consistency of the simulated tissue are also presented. This implementation also includes two manipulation tools, a move tool and a cut tool for interaction with the simulation. From the results, it is clear that the mass-springdamper model is a viable model that is possible to simulate in real-time on modern but commoditized hardware. With further development, this can be of great benefit to areas such as medical visualization and surgical simulation. / Målet med detta projekt var att utvärdera huruvida en modell baserad på massa-fjäderdämpare är meningsfull för att modellera biologisk vävnad. En metod för att automatiskt generera en sådan modell utifrån data tagen från medicinsk 3D-skanningsutrustning presenteras. Denna metod inkluderar både generering av punktmassor samt en algoritm för generering av länkar mellan dessa. Vidare beskrivs en implementation av en simulering av denna modell som körs i realtid genom att utnyttja den parallella beräkningskraften hos modern GPU-hårdvara via OpenCL. Denna implementation använder sig av fjärde ordningens Runge-Kutta-metod för förbättrad stabilitet jämfört med liknande implementationer. Svårigheten att bibehålla stabiliteten samtidigt som den simulerade vävnaden ges tillräcklig styvhet diskuteras genomgående. Flera observationer om modellstrukturens inverkan på den simulerade vävnadens konsistens presenteras också. Denna implementation inkluderar två manipuleringsverktyg, ett flytta-verktyg och ett skärverktyg för att interagera med simuleringen. Resultaten visar tydligt att en modell baserad på massa-fjäder-dämpare är en rimlig modell som är möjlig att simulera i realtid på modern men lättillgänglig hårdvara. Med vidareutveckling kan detta bli betydelsefullt för områden så som medicinsk bildvetenskap och kirurgisk simulering.

mass-spring-damper

model

modelling

biological tissue

3D

medical imaging

real-time

parallel computation

GPU

OpenCL

Runge-Kutta

move

cut

simulation

medical visualization

surgical simulation

massa-fjäderdämpare

modell

modellera

biologisk vävnad

3D

medicinsk skanningsutrustning

3D-skanning

realtid

parallell beräkning

GPU

OpenCL

Runge-Kutta

flytta

skär

medicinsk bildvetenskap

kirurgisk simulering

Software Engineering

Programvaruteknik