Fratoria DICOM RT Studio
Contents
1. Fratoria BV Westewagenstraat 60 Cc 3011AT Rotterdam AM The Netherlands Fratoria Email info fratoria com imaging the future Web www fratoria com Fratoria DICOM RT Studio User Manual Release 1 9 0 June 2011 C 1639 Contents A bsc imeem qao eee E Mn SUN UI M MU iE 5 1 1 Release Moo Peter cH mra mS 5 2 wWnstallatonminstructioPis uctor qaos ds 6 3 Minimum Hardware Requirements cccccssscccesseccceseeceenceceeececeueceseceseesceseeecesseneeesecessuecesseesenes 6 Z a me eS dM avuto Luc m ne eee ee 6 4 1 Loadihg froma TOMICE uon dd Fei oe de 6 4 2 POAC ICON a A A 7 4 3 Loading IMa fE EIE E Om 9 4 4 Loading active MOSATO Date Eu aiii AAA A aE 9 4 5 Sadie 4D data ireira UU TUR 10 4 6 ERE O NRI 10 4 7 Importing and exporting application configuratiON cocooocccnonnccnnnonnncnnnnnaconnonanononnnanccnnnnas 11 4 8 Using command lime arguments cor eee eri looo ae Acai na eo 11 A gh banc aah aatpawstoaucoapue serena ode aoe 12 5 1 SAVING Projects assi nda dnd A 12 5 2 Loading PEO e E NR T 12 Oi a O A A Dni eade ATO aeu 13 6 1 DAN OU eer M 13 6 2 WOOD AN epe mr EMEN 13 6 3 Navigation ana Interact 14 6 4 WIN WS acid iii erd 15 AMAge OnentatO Nas 15 e o En A Qiaiee 15 8 1 OO AA O NO 15 8 2 CONTE Sleep 16 8 3 Contour line Width ana COD ii ii eA 17 A LU O PRA o IL O 17 10 EB UE EE ERN 18 IDA AMIRT PIS E 19 T0 2 Dynamic AFC PIN add 19 10 2 1 Bea2. using Color Level and Color Window sliders also represented as red and blue vertical lines on the histogram see Figure 29 28 Normal and Cumulative histograms are supported Below the histogram there is a double ended slider to adjust the range of scalar values You can select predefined values for different organs from Profile drop down menu Alternatively you can specify your own combination of Level and Window values and store them locally as a user defined preset Poi Es Color Level 30 Y Color Window 300 Histogram Type Normal Figure 29 Image Window Level 17 Magnifier Magnifier allows you to zoom in on images details as if you were using a magnifying glass 29 Ele All 2D 3D Layout Help A DETER Mees Rm d Patient Pat1 Study ID 115 o PER T E E FS Tu Med_IMRT 1 1 Transversal Coronal Sagittal i Scalar Value Dose Value Sagittal Slice 257 of 512 Figure 30 Magnifier To switch on Magnifier click inside the viewing window where you would like to use Magnifier That will activate the window Now go to 2D gt Magnifier or click on the Magnifier button on the toolbar button 22 on Figure 8 and select zooming factor 1 10 Magnifier will appear in the active viewing window as shown on Figure 30 Move the magnifier with the mouse while pressing left mouse button to view image details To turn off Magnifier select Off from the Magnifier menu 18 Reportin
3. ACS REMOTE AE port 4006 suid 1 2 840 113745 101000 1008000 38220 6657 6448998 R S PACS NAME laet fratoria1 raet PACS REMOTE AE port 4006 suid 1 2 840 113745 101000 1008000 38220 6657 6448999 5 Projects 5 1 Saving projects Application state for a particular dataset can be saved as a project file It allows you to define the layout with visible dose beams ROIs etc and save it together with the location of the loaded dataset in an XML project file for fast retrieval To save a project file go to the menu File gt Save Project and provide a name for the XML files The following parameters will be saved Location of the current dataset either on hard disc or in PACS Active plan Visible ROIs Visible beams with control points Display of dose lines and colorwash Selected dose color scheme Display of absolute or normalized dose including POI for normalization All and visible dose values for selected color scheme DoseValues PET if selected together with PET color scheme window and level settings and the X Y Z shift Overlay image if selected including width and height of checks for check board display overlay opacity an color Forthe 3D rendering window Mode Show ROls Show POIs Show Beams Show Dose Window and Level setting for 2D image display The number of the displayed transversal coronal and sagittal slice Whether or not to display Live Beams Eye View Note that i
4. a beam in Visible Beams window Control Point drop down box will become enabled if the beam has multiple control points By clicking on the Control Point drop down box and holding the arrow keys you can loop through the list of control points An example of IMRT plan is shown on Figure 15 Transversal Slice 30 of 79 A Coronal Slice 299 of 512 P P D se W A ON 1 X Y Z Scalar Value Scalar Value Dose Value Dose Value F xX Y Z Scalar Value TTITIT TTITIT Dose Value Figure 15 IMRT plan visualization 10 2 Dynamic Arc Plans Visualizations of Elekta VMAT and Varian RapidArc plan are similar An example of an RapidArc plan with Beam Intensity Diagram and Live Beams Eye View is shown on Figure 16 19 Transversal Slice 40 of 79 Coronal Slice 257 of 512 xX Y Z Scalar Value Dose Value x Y Z Scalar Value Intesity diagram for boam Arc Dose Value Select Tissue Threshold Color Window Level Soft Tissue Hard Tissue E 9 10922 X Y Z Y 75 a c Window 32767 Scalar Value Dose Value Figure 16 Dynamic arc with Beams Eye View 10 2 1 Beam Intensity Diagram Beam Intensity Diagram can be displayed in transversal view For dynamic arc plans Show Beam Intensity Diagram option is enabled in Visible Beams window Figure 14 When this option is checked a diagram will be displayed as shown in transversal view on Figure 16 The height of the bins displays monitoring u
5. a window where you should select the location of the patid file Once selected the application will remember the location of this file and will not ask you next time when to try to load active MOSAIQ patient After confirming the patient id the application will open the Load Remote Dataset form as shown on Figure 3 fill in the patient id and send the query to the PACS server specified in the drop down menu You can then select and download dicom rt data of this patient from the PACS 4 5 Loading 4D data To load a 4D dataset go to File gt Load 4D Dataset The application will present the data in 3D as a volume looping through the timeframes The timeframe control see Figure 7 will become enabled so you can browse not only through the slices but also through individual frames in 2D 4 6 Object Linking After the data has been loaded into application you can verify the references between the objects in the dataset and create or remove links if necessary for correct visualization Insome scenarios for example when the scans have been exported separately from the plan they are stored most probably under different study uid s and the reference will be missing Another example could be several dose objects such as prescribed dose and portal dosimetry dose that need to be visualized on a set of CT scans and therefore should be linked to a plan To view the structure of the loaded dataset go to the menu File gt Object Linking A screen li
6. al Slice 257 of 512 LA Z X Y Z Scalar Value Scalar Value Dose Value i Dose Value Sagittal Slice 229 of 512 xX Y Z Scalar Value Dose Value iit HII Figure 42 Overlay options Using Overlay options you can define the check size opacity and select Colored option to view colored overlay You can move the checks of the overlay over the image with the mouse while holding the left mouse button 37 f Overlay Options Check width 50 mm Check height n 50 mm Y 10 O Colored Figure 43 Overlay options You can display ROIs POIs dose and beams together with the overlay image 22 Plan comparison To compare two plans side by side click on Compare Plans icon on the toolbar button 8 on Figure 8 Awindow will appear where you can select two plans from the loaded plans and specify the view for comparison transversal coronal or sagittal as show on Figure 44 Plan Comparison Plan 1 Plan 2 Select plan Plan SingleArc Dataset Patient P Select plan EMO MI E T View Transversal z View Transversal v Figure 44 4D options While Plan Comparison window is open the toolbar and the main menu of the application are accessible You can display ROIs POls dose and beams in Plan Comparison window for each selected plan by using the tools from the main menu or the toolbar The dose lines and colorwash are turned on and off for both plans simultaneously when you use these f
7. ce 302 of 512 Scalar Value Dose Value Figure 27 Position tracking in 2D and 3D 15 Cropping 27 The cropping tool allows slicing of volume and dose in 3D using 2D manipulators positioned in transversal coronal and sagittal viewing windows To activate cropping go to 2D gt Cropping or click on the Cropping button on the toolbar button 20 on Figure 8 Cropping filters will be displayed in transversal coronal and sagittal views as shown on Figure 28 Transversal cropping tool is a rectangle with grippers on each side and in the corners Using the grippers you can change the size of the rectangle When hovering with the mouse above the edges of the rectangle pan function will be activated and you can move the whole rectangle into a new position Coronal and sagittal cropping cuts the volume in height with two horizontal lines The volume between the lines will be displayed Changing cropping position in coronal view will automatically adjust it in sagittal view and vice versa Transversal Slice 34 of 79 Coronal Slice 291 of 512 X Y FE Scalar Value Scalar Value Dose Value Dose Value Sagittal Slice 302 of 512 X Scalar Value RotY RotZ MA OA Dose Value Figure 28 Cropping 16 Image Window Level To change Image Window Level values go to 2D gt Image Window Level or click on the Image Window Level button on the toolbar button 21 on Figure 8 The values can be adjusted
8. e Dose Values or click on the Show Dose drop down button on the toolbar button 5 on Figure 8 and select Visible Dose Values In the Visible Dose Values window see Figure 19 you can Switch between absolute and normalized dose Add Edit Remove points for color mapping Add and Remove dose value Select unselect dose values for absolute dose and percentages for normalized dose Visible Dose Values Schemes Default Color mapping Absolute Gy Normalized 5 Beam ISO Arc 1 Singles Figure 19 Visible Dose Values When viewing normalized dose you can select a normalization point which can be any of the POI s from the list To create a new scheme for visible dose values you can edit remove or add values to the color legend Depending on whether you create a scheme for absolute or normalized dose the value you 22 have to provide when editing or adding a point is in Gy or percentage Yu can also pick a color as shown on Figure 20 Add Dose Color Value HEU EY Figure 20 Add Dose Color You can also create color schemes with negative dose values These are used when presenting results of dose difference calculation of two plans in order to show which of two plans is better as described in section 11 4 From the defined color legend you can select specific values that you would like to display by checking the boxes next to the dose values removing existing values and adding new ones You can
9. e Range Last 7 Days Begin zondag 27 febwani 2011 End zondag 6 maat 2011 Patients Download Study Figure 3 Load Remote Dataset If you have not connected to your PACS server yet or do not have the right server on the list click on Add Server button The following window will appear m mm Server Name PACS Remote port 4000 Remote AE Title PACS SCP Local AE Title mynode1 Local port 104 Figure 4 Add Edit PACS Server Here you have to provide the name or ip address of the PACS server Remote port remote and local AE titles and Local port Your Local AE Title must match with the AE title added as a dicom node to the PACS server Note that you should properly add your application node as a dicom node to the PACS server The default Local port is 104 but if you have for example several DICOM listeners that cause a conflict you can adjust it After you have selected a PACS server you can download the data either 1 by searching for a study in the PACS and sending it to the DICOM RT Studio or 2 by using the Search feature in the DICOM RT Studio to select and download the study For 1 you have to click on Start SCP button and then search for a study in your PACS and send it to this dicom node For 2 you can define your search criteria and click on the Search button see Figure 3 If data are available a tree with patient names will be presented Every patient contains a list of studies A study contains a
10. e cursor up and down 6 4 Windows Via the menu Layout you can select which of the 4 windows should get enlarged Transversal Coronal Sagittal or 3D Alternatively you can select Tile Even for even size By dragging the vertical and horizontal separators you can also change the size of the windows 7 Image orientation Anterior Right Superior Inferior Left Z Posterior Y Figure 9 DICOM LPS Orientation The direction of the axes is defined fully by the patient s orientation The x axis is increasing to the left hand side of the patient The y axis is increasing to the posterior side of the patient The z axis is increasing toward the head of the patient The patient based coordinate system is a right handed system i e the vector cross product of a unit vector along the positive x axis and a unit vector along the positive y axis is equal to a unit vector along the positive z axis see Figure 9 8 ROIs 8 1 Visible ROIs If the loaded study contains ROls they will be displayed automatically in transversal view You can make contours visible invisible by first clicking on the Visible ROIs button on the toolbar button 2 on Figure 8 or selecting All Visible ROIs from the menu It will bring up window shown on Figure 10 where you can check uncheck ROIs 15 B Ring um PTV1 F PTVT Tu Med RM Ml Re Li Lunge Coronal and Sagittal contours Calculate for selected contours Figure 10 Visible ROI s The ap
11. e supported Rotate image with the mouse by pressing Ctrl left mouse button Move image with the mouse by pressing Shift left mouse button Zoom in and out by pressing right mouse button and moving the mouse cursor up and down Change window size The calculated DRR has a resolution of 300 by 300 points with spacing of 2 0 by 2 0 mm 13 Distance measurement You can measure distance between two points in transversal coronal and sagittal views Go to All gt Measuring Tool or click on the Measuring Tool button on the toolbar button 12 on Figure 8 Then click on a starting point in the image and draw the measuring line to another point The measured distance will be displayed on top of the viewing window see Figure 26 26 Transversal Slice 34 of 79 Measure Tool Length 82 mm Scalar Value Dose Value Figure 26 Measuring tool 14 Position Tracking With Position Tracking tool you can localize a point on any of 2D views and find the corresponding Slices in other 2D views In addition you can trace the selected point in 3D To use Position Tracking go to All gt Position Tracking orclick on the Position Tracking button on the toolbar button 13 on Figure 8 A cross will appear on the active slice that will follow the mouse cursor as shown on Figure 27 Transversal Slice 34 of 79 Coronal Slice 291 of 512 X Y Z Scalar Value Dose Value X Y Z Scalar Value Dose Value Sagittal Sli
12. eatures The ROIs POIs and the beams have to be turned on off per plan Therefore you have to active the plan first by selecting it from the drop down plan menu 2 on Figure 7 Plan comparison works on the same set of images 38 234D To load 4D datasets see section 4 5 Loading 4D data In 4D mode the application will enable the timeframe control control 3 on Figure 7 so you can browse through frames per slice In 3D viewing window a 4D dataset will loop through frames so you could see volume changes in time You can adjust the refresh rate by going to 3D gt 3D Settings or clicking on the 3D settings button on the toolbar button 32 on Figure 8 and selecting 4D Options tab in the 3D Rendering Settings window Set the frame speed in milliseconds and click on Apply see Figure 45 All 3D settings such as opacity and color can also be applied to 4D data Note that 4D datasets are typically very large So it might be the case that your machine will not have enough memory for a 4D dataset 3D Rendering Settings Frame speed 1000 ms Apply Figure 45 4D options 39
13. ed folder for loading from the hard disc presets for volume rendering You can export these settings to an xml file and import for example in the application on another workstation by going to File gt Export Configuration and File Import Configuration 4 8 Using command line arguments Using the following command line arguments the application can be launched and load automatically the data specified in the command line either from a local directory or from a PACS server L Load local dataset R Load remote dataset P path for the local dataset S PACS server ip address or name laet Local AET raet Remote AET port number remote port on PACS patid PATIENT ID suid Study UID seruid Serie UID Options L and R are mutually exclusive If only patid is provided all studies for this patient will be loaded either from a folder on the hard disc or from a pacs server Example for loading a local dataset 11 Fratoria Dicom RT Viewer exe L P C DicomData RTDataset suid 1 2 840 113745 101000 1008000 38220 6657 6448998 Example for loading a remote dataset Fratoria Dicom RT Viewer exe R S PACS NAME laet fratorial raet PACS REMOTE AE port 4006 suid 1 2 840 113745 101000 1008000 38220 6657 6448998 To load multiple datasets the L or R options can be used several times for example Fratoria Dicom RT Viewer exe R S PACS NAME laet fratorial raet P
14. f you saved a project file with a specific color scheme and intend to open it later on another computer and you need to have this color scheme on the target computer 5 2 Loading projects To load a project go to the menu File gt Load Project and select an XML project file The dataset will be automatically loaded and the application will be brought to a state according to the saved presets 12 6 Application Overview 6 1 Layout After you have loaded a data set the application would look like the one presented on Figure 7 MN TY 2 x Y Z Scalar Value Scalar Value Dose Value Dose Value Sagittal Slice 257 of 512 gt Ch Y te Scalar Value Dose Value Benen III Figure 7 Study loaded 9 The layout consists of the following components 1 Drop down menu with patients names from the loaded studies 2 Drop down menu with plans associated with the active study 3 Timeframe selector to browse through frames in 4D datasets 4 Thumbnail panel containing Transversal Coronal and Sagittal thumbnails 5 Toolbar with shortcuts to the main application features 6 Transversal view 7 Coronal view 8 Sagittal view 9 nteractive 3D viewer When you click inside a viewing window it becomes active By selecting items from the Layout menu you can make any of the viewing windows appear larger Alternatively you can drag the vertical and horizontal window separators to define you
15. face Volume rendering allows you to see internal organs similar to as they appear on X ray images Surface rendering extracts structures such as skin and bone and displays them as a surface You can switch between volume and surface rendering by going to 3D Visible In 3D gt Volume Rendering and Surface Rendering or by clicking on the Visible in 3D drop down button on the toolbar button 24 on Figure 8 Once in surface rendering mode the Surface Rendering window will appear where you can select a predefined type of surface rendering You can also open this window by clicking on the Surface Rendering Options button on the toolbar button 25 on Figure 8 or selecting it from the menu via 3D gt Surface Rendering Options 19 2 Skin with collimator outlining Skin with collimator outlining is a particular type of surface rendering If the viewer is in default volume rendering mode you have to switch to surface rendering first Therefore go to 3D Visible In 3D Surface Rendering or click on the Visible in 3D drop down button on the toolbar button 24 on Figure 8 and select Surface Rendering 32 In the Surface Rendering window select CT Skin Collimator Outlining as shown on Figure 33 This will present a list of all beams By clicking on the checkbox next to the beam name you can select unselect the beam that will be projected on the skin as a contour see example on Figure 34 If the beam has multiple control points the Con
16. g Tool The Reporting Tool generates images from the transversal coronal and sagittal views with projected beams dose and structures in a grid layout and saves them as png files To use the Reporting Tool first define what you would like to see in the transversal coronal and sagittal views by switching on off beams dose and structures The images in the report will appear exactly as you define them in those views Now go to 2D gt Reporting Tool or click on the Reporting Tool button on the toolbar button 23 on Figure 8 The window as shown on Figure 31 will appear 30 Reporting Tool Selection Transversal Coronal Sagittal AAA Output W Make report for transverse images Columns Make repart for coronal images 1 Make report for sagittal images 1 Generate Report s Figure 31 Reporting Tool image selection The Reporting Tool window contains 3 tabs for transversal coronal and sagittal thumbnailed images Click on the thumbnails to select images you would like to include in your report In the Output group check which image groups transversal coronal sagittal should be included and specify the number of columns per image group Figure 32 shows an example of a report with 6 transversal images in a 3 column layout 31 Figure 32 Reporting Tool output 19 3D viewing 19 1 Volume and Surface rendering The 3D viewing component is capable of rendering the data as a semitransparent volume and sur
17. ing Structure Set RT Structures Figure 2 Load Local Dataset There are two possibilities to load a dataset 1 2 You can either select a directory and click on Load button in the left panel The application will load all the dicom data from the subfolders You can have your scans RT images RT structures dose and plan files in different subfolders The application will combine the data that belong to the same plan You may load several plans at a time if they are stored in subfolders by selecting a higher level folder The application will ignore all non dicom data that might be present in the folder s You can select a directory from the left panel and click on Scan button The application will analyze the directory structure and present a tree view in the right panel as shown on Figure 2 The tree view has the following structure Patient name Study Study description Study id Series Series description Series type You can select one or more studies and one or more series Note If you select an RT dose object that does not have a corresponding plan or you do not select the corresponding plan the application will create an empty plan automatically during the data loading 4 2 Loading from a PACS To load a study from a PACS server select File gt Load Remote Dataset The window shown on Figure 3 will appear Load Remote Dataset sever PACS SCP Search Patient ID Last Name First Name Dat
18. ke an adjustment to your filter 33 When PET CT is rendered 3D settings can be applied to either CT or PET volume using the drop down menu at the top of the 3D Rendering Settings window disabled for single volume pa 3D Rendering Settings CT MRI Figure 35 Volume Opacity Figure 36 Volume Color To save a filter click on the Presets tab then click on Save As button and enter a new name Both opacity and color filter will be saved To load a filter just select one from the drop down menu in the Presets see Figure 37 Figure 37 3D Presets 34 19 4 Shade When using volume rendering you can also add Shade in some cases for a more contrast view However shade will typically slow down the rendering and make interaction rotation zoom pan a bit slower To select unselect shade go to 3D gt Shade or click on the Shade button on the toolbar button 33 on Figure 8 19 5 3D slice positions You can visualize positions of the active transversal coronal and sagittal slices in 3D Go to 3D gt 3D Slice Positions or click on the 3D Slice Positions button on the toolbar button 34 on Figure 8 In the 3D Slice Positions window check the slice positions you would like to see see Figure 38 Slices will be shown as semitransparent planes that move as you scroll through the data in 2D viewing windows Transversal Slice 34 of 79 Coronal Slice 291 of 512 rd aT me 5 x ob E M A u
19. ke the one show on Figure 6 will be presented Object Linking A M IET Figure 6 Links between RT objects 10 When hovering with the mouse above the objects a pop up window will be shown containing information about the object When hovering above a Plan object the links to all objects with the reference to the plan will be highlighted To enter editing mode click on Plan object This will highlight the links to the connected objects Click on the objects to make links Hold SHIFT while clicking to break links Click on Apply button to make the changes visible in the application The Reset button brings the object linking diagram to the state before the last change has been applied IMPORTANT Only one dose object can be connected to a plan Orphan dose is not allowed by the DICOM standard If you have an orphan dose in the dataset that has no reference to the plan or the plan object is missing the application will create an empty default plan and connect that dose to the newly created plan automatically 4 7 Importing and exporting application configuration All user settings in the application are kept in the xml configuration file It contains data from Figure 4 entered to establish connection with PACS system s user defined profiles for image window level settings user defined schemes for visible dose values user preference for calculation of coronal and sagittal contours manual vs automatic the last select
20. layed automatically in transversal coronal and sagittal views as spheres with a cross on the slice coinciding with the center of POI You can make POls visible invisible by going to All gt Visible POIs in the menu or clicking on the Visible POIs button on the toolbar button 3 on Figure 8 It will bring up window shown on Figure 13 where you can check uncheck POIs To show POls in 3D go to 3D Visible In 3D gt Show POIs or click on the Visible in 3D button on the toolbar button 24 on Figure 8 and select Show POIs Visible POIs Select Visible POls W Beam ISO Arc1 SingleArc v Masterplan normal Tu Med IMRT 1 W Beam ISO 1a1 Tu Med_IMRT 1 E Beam ISO 1b63 Tu Med_IMRT 1 7 Beam ISO 1c104 Tu Med_IMRT 1 I Beam ISO 14158 Tu Med_IMRT 1 FJ Beam 150 18188 Tu Med_IMRT 1 Beam 150 1 258 Tu Med IMRT 1 7 Beam ISO 19310 Tu Med_IMRT 1 Select All Deselect All Figure 13 Visible POls 10 Beams To turn on beams go to All gt Visible Beams or click on the Beams button on the toolbar button 4 on Figure 8 Window as shown on Figure 14 will appear Visible Beams Beams Control Point 0 No Wedge Figure 14 Visible Beams To view beams in 3D go to 3D gt Visible In 3D gt Show Beams or click on the Visible In 3D button on the toolbar button 24 on Figure 8 and select Show Beams 18 10 1 IMRT Plans IMRT plans have beams with more than one control point When you click on
21. list of modalities You can select patient one or more studies or just several modalities belonging to a study and click on the Download Study button The download process can be monitored as shown on Figure 1 4 3 Loading Image To load an image go to File gt Load Image and select a file The application will open it in the Image Viewer Figure 5 Image Viewer In the Image Viewer you can Adjust Level and Window settings using the sliders Rotate image with the mouse by pressing Ctrl left mouse button Move image with the mouse by pressing Shift left mouse button Zoom in and out by pressing right mouse button and moving the mouse cursor up and down Change window size 4 4 Loading active MOSAIQ patient The application can be connected to MOSAIQ from Elekta Impac to load the active patient id and obtain all plan data available for that patient from a PACS IMPORTANT In order to connect to MOSAIQ the parameter WorkstationlD must be specified in impac ini file on every workstation running MOSAIQ and where connectivity with Fratoria DICOM RT Studio should be implemented When opening a patient in MOSAIQ it will create a patid file that will contain the id of the active patient The patid file will have an extension corresponding to your WorkstationlD For example if you put WorkstationID 001 in impac ini MOSAIQ will generate patid 001 Go to File gt Load Active MOSAIQ Patient and you will be presented with
22. ls 23 Reporting tool generate reports containing selected images in a grid layout 3D tools 24 34 24 Visible in 3D define the type of rendering volume surface or PET CT or Live Beams Eye View and the items to be made visible in 3D POIs ROIs beams dose 25 Surface Rendering Options define the type of surface rendering skin bone etc including projection of the collimator outlining on the skin 26 31 3D orientation tools Front Back Right Left Top Bottom 32 3D Settings including Opacity Color mapping Presets and 4D options 33 Shade shade for volume rendering 34 3D Slice Positions display positions of 2D slices as planes in 3D 6 3 Navigation and interaction To browse through slices in 2D you can click on the thumbnails use keyboard arrows mouse scroll wheel or navigation buttons 15 19 on the toolbar Interaction in 2D includes Rotating image with the mouse by pressing Ctrl left mouse button Moving image with the mouse by pressing Shift left mouse button Zooming in and out by pressing right mouse button and moving the mouse cursor up and down Interaction in 3D includes 14 Rotation using RotX RotY RotZ scroll wheels or by pressing left mouse button and moving the mouse cursor You can also rotate around Z axis by pressing Ctrl and left mouse button Moving by pressing Shift and left mouse button Zooming in and out by pressing right mouse button and moving the mous
23. m Intensity Dias rain da 20 10 2 2 Liwve BeamssEye VIQGW neran n A O E A d tuy qux ire ve OCDE E VO Olde e be dS 21 11 1 Dose Ines ANG COlOLWAS Ni aia 22 112 Visible Dose Va lei dio 22 11 3 Dose Volume Histogram OVH uoces aveva oro NE exten Nasen ee reo en va xo ub no 23 11 4 Dose Accumulation and Dose Difference oooocccnnnnnconnconnnocnnnnnnnnnnonanonnnnnnnnnnononnnarnnnononnnns 24 P DOS ODIA E T 25 12 a SIDE Ard 25 13 Distance measurements dev ota artistes m ove oru sis 26 14 Meridie qilg le diga er MC 27 15 TOD e pP TEM 27 16 lage Mundo Level stas aii 28 17 AEEA RTT emet mH 29 18 REDORUING OO Met m E c 30 19 SOME WIDE Apia 32 191 Mol me and Sutface Tenderllg tradi 32 19 2 SKIN With colimator OUTING cis odessa eer A E Ue pe eA 32 L9g 9 SSDISGPUIDIBS a naa 33 E EN a ER T UL E eee eer 35 19 5 SD SICA posItloLiS uesexiud m A aa 35 20 PETOT A CT 35 ZU PETODUON Sat 36 21 VIEWING registered IMA E ees 37 22 Plan COMPARSA ee 38 23 A O 39 Device description Fratoria DICOM RT Studio is a software toolbox for advanced radiotherapy viewing analysis and contouring based on DICOM and DICOM RT It allows the user to read all relevant radiotherapy data including images plans dose ROIs POIs and RT images view this data interactively in 2D 3D 4D and evaluate plans Optionally the user may do contouring with the contouring plug in and save the resul
24. mulation Difference or click on the Show Dose drop down button on the toolbar button 5 on Figure 8 and select Dose Accumulation Difference In the window as shown on Figure 20 select two plans select from which of these plans the application should take the ROIs and POIs for the new plan if the original plans reference the same ROls POls then it does not matter which plan to check and specify the calculation type Accumulation or Difference Dose Accumulation Difference Select two plans Plan 1 SingleArc Use ROIS and POIS from this plan Plan 2 Tu Med IMRT 1 O Use ROIS and POIS from this plan Calculate Accumulation Difference Figure 22 Dose Accumulation Difference 24 For Dose Difference calculation the order of Plan 1 and Plan 2 is important as the result will be displayed using negative and positive dose values to show which of two plans gives more less dose The result of Dose Accumulation Difference will be a new plan that will be added to the drop down menu with plans This plan will contain the calculated RT dose object RT struct and CT images but no beams All operations such as DVH calculation or visualization of ROls on coronal and sagittal slices can be performed with the resulting plan Dose Accumulation Difference can be applied for any number of plans recursively by specifying two plans at a time and then selecting another plan together with the newly created plan and running the calcula
25. n requires a 64 bit Windows platform 4 Loading Data You can load a dataset either by loading it from a local folder or from a PACS server You can also load separate images and 4D datasets from a local folder The process of data loading can be monitored in the console window see Figure 1 Study Loading Info Creating Thumbnails Study Loading Finished Loading DRR images Loading DRR images pading dose Loading beams Figure 1 Study Loading Info You can load more than one dataset if your machine has enough memory and switch between them using drop down menu with patient names see Figure 5 4 1 Loading from a folder In order to load a dataset from a local folder you have to select from the main menu File gt Load Local Dataset and then select a folder from a tree structure Load Local Dataset Select Folder Scan Results d Local Fixed Disk C EF TPATI CD ROM Disc D E vi Study 1 Spezial 4 Thorax Erwachsener 1 J Local Fixed Disk E 7 Series 1 ARIA RadOnc Plans RT Plan lia Local Fixed Disk F W Series 2 Eclipse Doses RT Dose hy Downloads Series 3 Topogramm 3 0 T80s DRR Images x Pati F Series 4 Thorax 5 0 B41s Image Data V Series 5 No Description DRA Images 1 j v Series 6 Dose for Tu Med_IMRT 1 RT Dose 9 Series 7 Tu Med_IMRT 1 14 8cm T Oem nre i 2cm n cran RT Plan v Series 8 Nucletron Oncentra Anatomy Model
26. nits MUs stored as a difference between two control points Hovering with the mouse above the bins highlights the selected bin and displays the MUs gantry angles for two control points and gantry step size in degrees In avoidance region the MUs are equal to O for each control point The corresponding diagram contains a red sector for all MU 0 as shown on Figure 17 Transversal Slice 57 of 113 VOIDANCE gle 28 8 Figure 17 Avoidance region of a RapidArc plan 20 10 2 2 Live Beams Eye View You can switch the default volume rendering to live Beams Eye View a live DRR generator for dynamic arc plans Therefore go to the menu 3D gt Visible In 3D gt Live Beams Eye View or click on the Visible In 3D button on the toolbar button 24 on Figure 8 and select Live Beams Eye View Select a beam from Visible Beams window A DRR with projected vectorized collimator outlining will appear in the bottom right window as shown on Figure 16 You can adjust the tissue threshold by setting the value with the slider towards soft or hard tissue change level and window settings and add ROls to DRR By pressing the right mouse button and moving the cursor up and down you can zoom in and out When looping through the list of beam control points a new DRR will be automatically generated for each control point Live Beams Eye View feature generates DRRs using ray cast method For performance reasons DRRs are produced at lower quality of 133 by 133 p
27. o 10 The application will ask you whether you want to apply this change to all contours in the ROI this contour belongs to If you select Yes all contours in this ROI will be given selected line thickness If you choose No the change will be applied just to the selected contour To change contour color select a contour as described in section 6 2 Contour selection Now go to All gt Line Color or click on the Line Color button on the toolbar button 11 on Figure 8 and select a color from the color pallet window that will appear If you click Ok to confirm your color choice the application will ask you whether you want to apply this change to all contours in the ROI this contour belongs to If you select Yes all contours in this ROI will be given the selected color If you choose No the change will be applied just to the selected contour To see the changes you applied to the selected contour or ROI in 3D go to 3D Visible In 3D gt Show ROls or click on the Visible In 3D button on the toolbar button 24 on Figure 8 and select Show ROIs ROIs are best viewed with semitransparent volume rendering as shown on Figure 12 Transversal Slice 18 of 79 Coronal Slice 257 of 512 x Y x Y Scalar Value Scalar Value Dose Value Dose Value Sagittal Slice 257 of 512 X Y Scalar Value Dose Value Figure 12 Selected contour 9 POIs 17 If the loaded study contains POIs they will be disp
28. of the viewer buttons 1 and 2 on Figure 24 to scroll through stored DRR images and use Color Level and Color Window sliders to adjust Level and 25 Window values When Apply to all images is checked the application will apply the user defined Level and Window values to all images shown in the DRR window 3 4 1 z DRR Viewer x Ge E DRR Image 6 of 14 Add ROI To DRR E l DRR Image 15 of 15 Im y N o L RH Vi Select Beam For DRR Select Beam and Control Point Beam 1a1 Control Point 0 Select Tissue Threshold Soft Tissue Hard Tissue 5 Value 75 Gantry 1 Collimator 02 Color Level 901 Color Level 10922 Color Window 1311 Color Window 32767 O Apply to all images O Apply to all images Default Figure 24 DRR beam selection Figure 25 DRR with collimator outlines To generate a DRR with vectorized collimator outlining click on button 3 as shown on Figure 24 Select Beam for DRR window will appear where you can select a beam beam control point if available and set the tissue threshold towards soft or hard tissue for DRR calculation After the calculation has been completed you will see the output as shown on Figure 25 You can turn the collimator outlining on and off using button 4 on Figure 25 You can also select ROI from the drop down list that will be projected on the DRR The following operations for manipulation with the image ar
29. oints with spacing of 4 5 by 4 5 mm By pressing on the DRR button in the upper right corner of the Live Beams Eye View window you will obtain a high resolution DRR of 300 by 300 points with spacing of 2 0 by 2 0 mm 11 Dose Dose is visualized in 2D with lines and colorwash and as a wireframe in 3D see Figure 18 Coronal Slice 257 of 512 Transversal Slice 40 of 79 x VW Scalar Value _Dose Value A Scalar Value Dose Value Sagittal Slice 257 of 512 X Scalar Value RotY Rot ITEEEEEEEE CORRE REEE Doze Value Figure 18 Dose lines and colorwash To see absolute dose values hover with the mouse above the image Absolute dose values in Gy will be displayed at the bottom of the viewing window 21 You can use the Cropping tool to cut through volume and dose and see internal dose distribution in 3D see section 13 Cropping 11 1 Dose lines and colorwash To visualize dose go to All gt Dose gt Show Dose Lines or click on the Show Dose drop down button on the toolbar button 5 and select Show Dose Lines This will also turn on dose visualization in 3D To add dose colorwash visualization go to All gt Dose gt Show Dose Colorwash or click on the Show Dose drop down button on the toolbar button 5 on Figure 8 and select Show Dose Colorwash 11 2 Visible Dose Values You can adjust visible dose lines using Visible Dose Values screen Go to All gt Dose gt Visibl
30. on in PET Options window Go to All gt PET gt PET Options or click on the Show PET drop down button on the toolbar button 6 on Figure 8 and select PET Options You can chose from one of the widely use PET color schemes adjust Level and Window settings and specify transparency threshold see Figure 40 Adjusting the Level and Window settings works similar to the Image Level Window for CT images allowing to display a selected range of PET values The application supports only pre registered PET CTs If PET is not aligned properly with CT you can adjust PET s position by specifying translation in X Y and Z direction on the Move tab see Figure 41 You can use both positive and negative numbers to specify direction of translation 36 PET Options PET Options Color Move Color Move pee ee p Translate X 0 00 Y 0 00 Z 0 00 millimeter Apply Color Level 3707 y Color Window 6672 Y Opacity 40 Y Figure 40 PET color opacity Figure 41 PET position 21 Viewing registered images Registered images can be viewed using Overlay feature The registration data should be stored in DICOM registration modality If multiple image sets are loaded click on button 7 on Figure 8 to load an image set as a overlay Registration info loaded will appear after the name of the dataset if registration data is available The overlay image is visualized as chessboard as shown on Figure 42 Transversal Slice 64 of 102 Coron
31. plication can also calculate coronal and sagittal ROIs based on transversal ones This calculation runs on the background in a separate process and does not interfere with the normal operation In the Visible ROIs window select the ROIs and click Calculate for selected contours button Individual contours of each ROI will appear on the coronal and sagittal slices as soon as they are calculated To show ROIs in 3D go to 3D gt Visible In 3D gt Show ROIs or click on the Visible In 3D button on the toolbar button 24 on Figure 8 and select Show ROIs ROIs are best viewed with semitransparent volume rendering as shown on Figure 11 Figure 11 ROIs in 3D 8 2 Contour selection To select a contour first go to All gt Select Contour or click on the Select Contour button on the toolbar button 9 on Figure 8 Click then on or close to a contour that you would like to select Contour name will appear at the bottom of the viewing window and an arrow will point on the selected contour Contours can be selected in transversal coronal and sagittal views 16 8 3 Contour line width and color You can adjust the line width and color of the selected contour for better visibility in 2D and in particular in 3D view To change the line width first select a contour as described in section 6 2 Contour selection Now go to All gt Line Width or click on the Line Width button on the toolbar button 10 on Figure 8 and select line thickness 1 t
32. r own layout 6 2 Toolbar 910 11 513 14 15 17 419 202122 23 24 Fe a E HAS e gt e Oal Bv Figure 8 Toolbar 25 262 28293031 323334 bbb bdilo 234 O oV v 28 13 The toolbar is split into 3 sections Generic 2D en 3D tools All functions can also be called from the main menu Generic tools 1 14 DRR Viewer view stored DRR s and or generate DRR s with collimator outlines ROIs select visible ROIs POI s select visible POI s Beams select visible Beams and beam control points Dose tools to show dose lines and colorwash DVH and define visible dose values PET select PET scans to project on CT and set preferences with PET Options tool Overlay view registered images Compare plans view two plans side by side Contour selector select contours in a ROI 10 Contour line width change line with of selected contour ROI 11 Contour line color change color of selected contour ROI 12 Measuring tool measure distance between 2 points on a slice 13 Position Tracking track position of a point selected in a 2D view in other views 14 Reset reset all properties for all viewers O CON DU BPWN FE 2D tools 15 23 15 19 Slice scrolling tools First Previous Loop Pause Next Last 20 Cropping crop volume using 2D manipulators 21 Image Window Level adjust Window Level settings 22 Magnifier zoom in out on image detai
33. s r IE F i X Y Z 3D Slice Positions Scalar Value Dose Value W Display transversal sl lice position Sagittal Slice 302 of 512 vw Display coronal slice position k Display sagittal slice position P E HEN Scalar Value Dose Value Figure 38 3D slice positions 20 PET CT PET CT consists of two volumes that will be loaded together To activate PET visualization on CT go to All gt PET or click on the Show PET button on the toolbar button 6 on Figure 8 and select a PET volume There might be more than one PET available for the same set of CT scans To display PET in 3D go to 3D gt Visible In 3D gt CT amp PET or click on the Visible In 3D drop down button on the toolbar button 24 on Figure 8 and select CT amp PET Please be aware that PET CT 35 rendering in 3D requires substantial CPU resources to merge two volumes and will take time to calculate the final view Coronal Slice 257 of 512 Transversal Slice 68 of 134 X Y 7 X Y E Scalar Value Scalar Value Dose Value Dose Value Sagittal Slice 257 of 512 HI n Ennii X Y F7 Scalar Value Dose Value Figure 39 PET CT with beams ROIs and dose When rotating PET CT volume in 3D the software will decrease the level of details while spinning and will recalculate the high quality presentation when spinning is stopped 20 1 PET options You can adjust PET color setting and PET positi
34. save your color scheme under a new name 11 3 Dose Volume Histogram DVH To view DVH go to All gt Dose gt Show Dose Volume Histogram or click on the Show Dose drop down button on the toolbar button 5 on Figure 8 and select Show Dose Volume Histogram To calculate DVH check one or more ROIs in the Active Plan tab for which you would like to calculate the DVH optionally if more than one plan is opened select the plan to compare in the Compare tab select the line type and the ROIs check the option Use calculated DVH which is checked by default if no DVH is stored when DVH calculation is completed the Combined tab will contain the ROIs from the selected plans together with DVH statistics For faster calculation you can change the value of the Acceleration factor By default the acceleration factor equals 1 which means that the algorithm will iterate through every dose voxel Other values for acceleration factor are 2 and 3 which means that the algorithm will iterate through every second resp third voxel The accuracy of the calculation is that lower but you can get a impression of how DVH would look like much faster especially for large ROls However it is not recommended to use values of the acceleration factor other than 1 for smaller ROI You can switch between absolute and normalized values on the X axis Normalization can be done for any available POI that you can select from the drop down box By ho
35. sualization of merged CT MR images with projected RT objects Side by side comparison of two plans on the same set of CT images Improved DVH module with the ability to compare calculated DVHs of two plans and DVH statistics Project files allowing to save study location with viewing presets 5 Result of Dose Difference calculation shows which of two plans is better using positive and negative dose 6 Improved visualization of Beam Intensity Diagram for dynamic arc plans 7 Labels for identification of dose objects e g total dose dose per beam in Dose Objects overview 8 Study date added to the PACS search results window 2 Installation Instructions In order to install Fratoria DICOM RT Studio you first have to obtain your hardware ID Therefore run FratoriaGetIDS exe and copy the generated unique hardware ID When contacting Fratoria you will be asked for this ID to generate a serial number for your license To install the application just run the msi installation file you might have to unzip it first and follow the instructions on the screen At the end of the installation you will be asked to enter your serial number 3 Minimum Hardware Requirements Two versions of the application are available 32 bit and 64 bit The 32 bit version will run on any Windows based PC laptop with Windows XP Windows Vista or Windows 7 at least 1GB of RAM 1024 x 768 screen resolution and a reasonably modern mainstream GPU The 64 bit versio
36. t as DICOM RT structure for use by other systems in the delivery of treatment to a patient The contouring module is described in the user manual for contouring The system runs as a stand alone application on Microsoft Windows platform Intended use The software is to be used by radiation oncology professionals for review and evaluation of radiotherapy plans and all related imaging data contouring for the purposes of creating patient treatment plans in radiotherapy Treatment Planning Systems with the contouring data generated by the contouring module for Fratoria DICOM RT Studio This is applicable to contouring module only Intended audience This manual is written for radiation oncology professionals and for Fratoria software service engineers You should make sure that you have thoroughly read and completely understand the manuals and release notes that are delivered with the software If you suspect that the system does not operate according to this manual discontinue its use and contact Fratoria customer support by email via info fratoria com CE Marking Fratoria DICOM RT Studio is CE market to the Medical Device Directive 93 42 EEC C 1639 Disclaimer All rights reserved 2011 Fratoria BV All the information in this document is intellectual property of Fratoria BV The content of this document may not be reproduced or published without written permission from Fratoria BV 1 What s new 1 1 Release 1 9 Vi
37. tion again 11 5 Dose Objects A study can contain several dose objects By default the application displays the total dose for the plan but other dose objects can be selected if available Go to All gt Dose gt Dose Objects or click on the Show Dose drop down button on the toolbar button 5 on Figure 8 and select Dose Objects In the window as shown on Figure 21 individual dose objects can be selected If you select several objects the displayed dose is the sum of these objects By default the application shows the total plan dose dose object PLAN If this object is not present it than searches for dose per beam objects dose object BEAM and displays the sum of these objects to get the total dose r Dose Objects Dose object 1 CONTROL POINT Isv Dose object 2 CONTROL POINT Isv Dose object 3 CONTROL POINT rsa Dose object 4 CONTROL POINT rsa Dose object 5 BEAM rsv Dose object 6 BEAM lsv Dose object 7 BEAM rsa Dose object 8 BEAM rsv aanv Dose object 9 FRACTION lv Dose object 10 PLAN Figure 23 Dose Objects 12 DRR The DRR Viewer displays stored DRR images and allow you to generate DRRs per beam and beam control point The vectorized collimator outlining will be projected on the image and can be switched on and off To open DRR viewer go to All gt DRR Viewer or click on the DRR Viewer button on the toolbar button 1 on Figure 8 You can use arrows on top
38. trol Point drop down box will be enabled so you can select control point to use in the beam projection Additionally for a better view you can switch on beam geometry visualization in 3D by going to 3D gt Visible In 3D or clicking on Visible In 3D drop down button on the toolbar button 24 on Figure 8 and turning on Show Beams option Surface Rendering CT Skin Collimator Outlining Control Point Q Figure 33 Skin Rendering Figure 34 Skin Rendering with collimator outlines window 19 3 3D settings 3D settings allow you to define volume view using opacity and color mapping You can define your own filters and store them as presets or use default filters 3D rendering settings apply to volume rendering only They are not intended and do not work for surface rendering To change 3D settings go to 3D gt 3D Settings or click on the 3D settings button on the toolbar button 32 on Figure 8 The 3D Rendering Settings window has 4 tabs Opacity Color Presets and 4D Options The Opacity function allows you to define a filter for transparency by adding points and placing them in the histogram of grey values to create a transfer function as shown on Figure 35 The Color function works in a similar way by mapping color values to scalar values in a specified range see Figure 36 Both Opacity and Color functions work interactively in real time which means that you will see the output in volume rendering as soon as you ma
39. vering with the mouse above the DVH lines you can see the exact values for absolute dose and volume If you hover with the mouse above the grid lines in the Combined tab the corresponding ROI will be highlighted on the graph Figure 21 shows an example DVH of two plans 23 DoseVolumeHistogram c t9 Ee Active Plan Compare Combined Options ROI s ROI Min A v Use calculated DVH e Mean Dose Y Show absolute values O Normalize for POI Beam ISO Arc1 SingleArc Plan Color Visible RO Name Tu Med_IMRT 1 MN GTV1 Tumor GTV 65 67 Gy Single Arc GTV1 Tumor GTV 6720Gy 6229Gy Acceleration factor 1 M SingleArc i B v AVOIDANCE 4565cm 3 64 Gy Tu Med_IMRT 1 AVOIDANCE 2385 9 cm 0 83 Gy 71 68 Gy AVOIDANCE 2387 5 cm 1 47 Gy 67 20 Gy ROI Volume gt gt 0 0 000 7 168 14 337 21 505 8 673 5 841 43 010 50 178 57 348 34 515 71 683 Figure 21 DVH DVH calculation runs on a separate thread so you can continue working with the application while the calculation takes place on the background The calculated DVH is kept in the memory while the dataset is opened so closing the DVH window and opening it again does not require recalculation of the DVH 11 4 Dose Accumulation and Dose Difference If the loaded dataset consists of 2 or more plans the application can calculate dose accumulation and dose difference provided that the plans reference the same set of CT scans Go to All gt Dose gt Dose Accu
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