diff --git a/Modules/MitkExt/Interactions/mitkSegTool2D.cpp b/Modules/MitkExt/Interactions/mitkSegTool2D.cpp
index ac05688a77..8d3fdaed09 100644
--- a/Modules/MitkExt/Interactions/mitkSegTool2D.cpp
+++ b/Modules/MitkExt/Interactions/mitkSegTool2D.cpp
@@ -1,395 +1,393 @@
 /*=========================================================================
 
 Program:   Medical Imaging & Interaction Toolkit
 Language:  C++
 Date:      $Date$
 Version:   $Revision$
 
 Copyright (c) German Cancer Research Center, Division of Medical and
 Biological Informatics. All rights reserved.
 See MITKCopyright.txt or http://www.mitk.org/copyright.html for details.
 
 This software is distributed WITHOUT ANY WARRANTY; without even
 the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
 PURPOSE.  See the above copyright notices for more information.
 
 =========================================================================*/
 
 #include "mitkSegTool2D.h"
 #include "mitkToolManager.h"
 
 #include "mitkDataStorage.h"
 #include "mitkBaseRenderer.h"
 
 #include "mitkPlaneGeometry.h"
 
 #include "mitkExtractImageFilter.h"
 #include "mitkExtractDirectedPlaneImageFilter.h"
 
 //Include of the new ImageExtractor
 #include "mitkExtractDirectedPlaneImageFilterNew.h"
 #include "mitkPlanarCircle.h"
 #include "mitkOverwriteSliceImageFilter.h"
 #include "mitkOverwriteDirectedPlaneImageFilter.h"
 
 #include "mitkGetModuleContext.h"
 
 //Includes for 3DSurfaceInterpolation
 #include "mitkImageToContourFilter.h"
 #include "mitkSurfaceInterpolationController.h"
 
 //includes for resling and overwriting
 #include <mitkExtractSliceFilter.h>
 #include <mitkVtkImageIdxReslice.h>
 #include <vtkSmartPointer.h>
 #include <vtkImageData.h>
 
 
 
 #define ROUND(a)     ((a)>0 ? (int)((a)+0.5) : -(int)(0.5-(a)))
 
 mitk::SegTool2D::SegTool2D(const char* type)
 :Tool(type),
  m_LastEventSender(NULL),
  m_LastEventSlice(0),
  m_Contourmarkername ("Position"),
  m_ShowMarkerNodes (true),
  m_3DInterpolationEnabled (true)
 {
   // great magic numbers
   CONNECT_ACTION( 80, OnMousePressed );
   CONNECT_ACTION( 90, OnMouseMoved );
   CONNECT_ACTION( 42, OnMouseReleased );
   CONNECT_ACTION( 49014, OnInvertLogic );
 
 
 }
 
 mitk::SegTool2D::~SegTool2D()
 {
-	m_Map = NULL;
-
 }
 
 bool mitk::SegTool2D::OnMousePressed (Action*, const StateEvent* stateEvent)
 {
   const PositionEvent* positionEvent = dynamic_cast<const PositionEvent*>(stateEvent->GetEvent());
   if (!positionEvent) return false;
 
   if ( positionEvent->GetSender()->GetMapperID() != BaseRenderer::Standard2D ) return false; // we don't want anything but 2D
 
   m_LastEventSender = positionEvent->GetSender();
   m_LastEventSlice = m_LastEventSender->GetSlice();
 
   return true;
 }
 
 bool mitk::SegTool2D::OnMouseMoved   (Action*, const StateEvent* stateEvent)
 {
   const PositionEvent* positionEvent = dynamic_cast<const PositionEvent*>(stateEvent->GetEvent());
   if (!positionEvent) return false;
 
   if ( m_LastEventSender != positionEvent->GetSender() ) return false;
   if ( m_LastEventSlice  != m_LastEventSender->GetSlice() ) return false;
 
   return true;
 }
 
 bool mitk::SegTool2D::OnMouseReleased(Action*, const StateEvent* stateEvent)
 {
   const PositionEvent* positionEvent = dynamic_cast<const PositionEvent*>(stateEvent->GetEvent());
   if (!positionEvent) return false;
 
   if ( m_LastEventSender != positionEvent->GetSender() ) return false;
   if ( m_LastEventSlice  != m_LastEventSender->GetSlice() ) return false;
 
   return true;
 }
 
 bool mitk::SegTool2D::OnInvertLogic(Action*, const StateEvent* stateEvent)
 {
   const PositionEvent* positionEvent = dynamic_cast<const PositionEvent*>(stateEvent->GetEvent());
   if (!positionEvent) return false;
 
   if ( m_LastEventSender != positionEvent->GetSender() ) return false;
   if ( m_LastEventSlice  != m_LastEventSender->GetSlice() ) return false;
 
   return true;
 }
 
 bool mitk::SegTool2D::DetermineAffectedImageSlice( const Image* image, const PlaneGeometry* plane, int& affectedDimension, int& affectedSlice )
 {
   assert(image);
   assert(plane);
 
   // compare normal of plane to the three axis vectors of the image
   Vector3D normal       = plane->GetNormal();
   Vector3D imageNormal0 = image->GetSlicedGeometry()->GetAxisVector(0);
   Vector3D imageNormal1 = image->GetSlicedGeometry()->GetAxisVector(1);
   Vector3D imageNormal2 = image->GetSlicedGeometry()->GetAxisVector(2);
 
   normal.Normalize();
   imageNormal0.Normalize();
   imageNormal1.Normalize();
   imageNormal2.Normalize();
 
   imageNormal0.Set_vnl_vector( vnl_cross_3d<ScalarType>(normal.Get_vnl_vector(),imageNormal0.Get_vnl_vector()) );
   imageNormal1.Set_vnl_vector( vnl_cross_3d<ScalarType>(normal.Get_vnl_vector(),imageNormal1.Get_vnl_vector()) );
   imageNormal2.Set_vnl_vector( vnl_cross_3d<ScalarType>(normal.Get_vnl_vector(),imageNormal2.Get_vnl_vector()) );
 
   double eps( 0.00001 );
   // transversal
   if ( imageNormal2.GetNorm() <= eps )
   {
     affectedDimension = 2;
   }
   // sagittal
   else if ( imageNormal1.GetNorm() <= eps )
   {
     affectedDimension = 1;
   }
   // frontal
   else if ( imageNormal0.GetNorm() <= eps )
   {
     affectedDimension = 0;
   }
   else
   {
     affectedDimension = -1; // no idea
     return false;
   }
 
   // determine slice number in image
   Geometry3D* imageGeometry = image->GetGeometry(0);
   Point3D testPoint = imageGeometry->GetCenter();
   Point3D projectedPoint;
   plane->Project( testPoint, projectedPoint );
 
   Point3D indexPoint;
 
   imageGeometry->WorldToIndex( projectedPoint, indexPoint );
   affectedSlice = ROUND( indexPoint[affectedDimension] );
   MITK_DEBUG << "indexPoint " << indexPoint << " affectedDimension " << affectedDimension << " affectedSlice " << affectedSlice;
 
   // check if this index is still within the image
   if ( affectedSlice < 0 || affectedSlice >= static_cast<int>(image->GetDimension(affectedDimension)) ) return false;
 
   return true;
 }
 
 mitk::Image::Pointer mitk::SegTool2D::GetAffectedImageSliceAs2DImage(const PositionEvent* positionEvent, const Image* image)
 {
   if (!positionEvent) return NULL;
 
   assert( positionEvent->GetSender() ); // sure, right?
   unsigned int timeStep = positionEvent->GetSender()->GetTimeStep( image ); // get the timestep of the visible part (time-wise) of the image
 
   // first, we determine, which slice is affected
   const PlaneGeometry* planeGeometry( dynamic_cast<const PlaneGeometry*> (positionEvent->GetSender()->GetCurrentWorldGeometry2D() ) );
 
   if ( !image || !planeGeometry ) return NULL;
 
 	//Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk reslicer
 	vtkSmartPointer<mitkVtkImageIdxReslice> reslice = vtkSmartPointer<mitkVtkImageIdxReslice>::New();
 	//set to false to extract a slice
 	reslice->SetOverwriteMode(false);
 	reslice->Modified();
 
 	//use ExtractSliceFilter with our specific vtkImageReslice for overwriting and extracting
 	mitk::ExtractSliceFilter::Pointer extractor =	mitk::ExtractSliceFilter::New(reslice);
 	extractor->SetInput( image );
 	extractor->SetTimeStep( timeStep );
 	extractor->SetWorldGeometry( planeGeometry );
 	extractor->SetVtkOutputRequest(false);
 	extractor->SetResliceTransformByGeometry( image->GetTimeSlicedGeometry()->GetGeometry3D( timeStep ) );
 
 	extractor->Modified();
 	extractor->Update();
 
 	Image::Pointer slice = extractor->GetOutput();
 
 	/*At this point we have to adjust the geometry because reslicing is based on vtk.
 		For oblique planes the calculation of the extent has negative minimum values.
 		As these values are used as some kind of geometry information by the rendering,
 		they have to be considered in the projection function of the conoutring.
 	 */
 
 	//we just shift the origin in each direction
 	Vector3D axis0 = slice->GetGeometry()->GetAxisVector(0);
 	Vector3D axis1 = slice->GetGeometry()->GetAxisVector(1);
 	axis0.Normalize();
 	axis1.Normalize();
 
 	Point3D origin = slice->GetGeometry()->GetOrigin();
 	
 	//these are the negative minimum values.
 	int offsetX = extractor->GetVtkOutput()->GetExtent()[0];
 	int offsetY = extractor->GetVtkOutput()->GetExtent()[2];
 
 	//consider the spacing in each direction
 	Vector3D spacing = slice->GetGeometry()->GetSpacing();
 	
 	//adapt the origin. Note that for orthogonal planes the minima are '0' and thus the origin stays the same.
 	origin += (axis0 * (offsetX * spacing[0])) + (axis1 * (offsetY * spacing[1]));
 
 	slice->GetGeometry()->SetOrigin(origin);
 
 
 	return slice;
 }
 
 mitk::Image::Pointer mitk::SegTool2D::GetAffectedWorkingSlice(const PositionEvent* positionEvent)
 {
   DataNode* workingNode( m_ToolManager->GetWorkingData(0) );
   if ( !workingNode ) return NULL;
 
   Image* workingImage = dynamic_cast<Image*>(workingNode->GetData());
   if ( !workingImage ) return NULL;
 
   return GetAffectedImageSliceAs2DImage( positionEvent, workingImage );
 }
 
 mitk::Image::Pointer mitk::SegTool2D::GetAffectedReferenceSlice(const PositionEvent* positionEvent)
 {
   DataNode* referenceNode( m_ToolManager->GetReferenceData(0) );
   if ( !referenceNode ) return NULL;
 
   Image* referenceImage = dynamic_cast<Image*>(referenceNode->GetData());
   if ( !referenceImage ) return NULL;
 
   return GetAffectedImageSliceAs2DImage( positionEvent, referenceImage );
 }
 
 void mitk::SegTool2D::WriteBackSegmentationResult (const PositionEvent* positionEvent, Image* slice)
 {
   const PlaneGeometry* planeGeometry( dynamic_cast<const PlaneGeometry*> (positionEvent->GetSender()->GetCurrentWorldGeometry2D() ) );
 
   DataNode* workingNode( m_ToolManager->GetWorkingData(0) );
   Image* image = dynamic_cast<Image*>(workingNode->GetData());
 
 	//Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk reslicer
 	vtkSmartPointer<mitkVtkImageIdxReslice> reslice = vtkSmartPointer<mitkVtkImageIdxReslice>::New();
 
 	//Set the slice as 'input'
 	reslice->SetInputSlice(slice->GetVtkImageData(this->m_TimeStep));
 
 	//set overwrite mode to true to write back to the image volume
 	reslice->SetOverwriteMode(true);
 	reslice->Modified();
 
 	mitk::ExtractSliceFilter::Pointer extractor =	mitk::ExtractSliceFilter::New(reslice);
 	extractor->SetInput( image );
 	extractor->SetTimeStep( this->m_TimeStep );
 	extractor->SetWorldGeometry( planeGeometry );
 	extractor->SetVtkOutputRequest(true);
 	extractor->SetResliceTransformByGeometry( image->GetTimeSlicedGeometry()->GetGeometry3D( this->m_TimeStep ) );
 
 	extractor->Modified();
 	extractor->Update();
 
 	//the image was modified within the pipeline, but not marked so
 	image->Modified();
 	
   if ( m_3DInterpolationEnabled )
   {
     slice->DisconnectPipeline();
     unsigned int pos = this->AddContourmarker(positionEvent);
     ImageToContourFilter::Pointer contourExtractor = ImageToContourFilter::New();
     contourExtractor->SetInput(slice);
     contourExtractor->Update();
     mitk::Surface::Pointer contour = contourExtractor->GetOutput();
     mitk::ServiceReference serviceRef = mitk::GetModuleContext()->GetServiceReference<PlanePositionManagerService>();
     PlanePositionManagerService* service = dynamic_cast<PlanePositionManagerService*>(mitk::GetModuleContext()->GetService(serviceRef));
     mitk::SurfaceInterpolationController::GetInstance()->AddNewContour( contour, service->GetPlanePosition(pos));
     contour->DisconnectPipeline();
   }
 }
 
 void mitk::SegTool2D::SetShowMarkerNodes(bool status)
 {
     m_ShowMarkerNodes = status;
 }
 
 void mitk::SegTool2D::Enable3DInterpolation(bool status)
 {
     m_3DInterpolationEnabled = status;
 }
 
 unsigned int mitk::SegTool2D::AddContourmarker ( const PositionEvent* positionEvent )
 {
   const mitk::Geometry2D* plane = dynamic_cast<const Geometry2D*> (dynamic_cast< const mitk::SlicedGeometry3D*>(
     positionEvent->GetSender()->GetSliceNavigationController()->GetCurrentGeometry3D())->GetGeometry2D(0));
 
   mitk::ServiceReference serviceRef = mitk::GetModuleContext()->GetServiceReference<PlanePositionManagerService>();
   PlanePositionManagerService* service = dynamic_cast<PlanePositionManagerService*>(mitk::GetModuleContext()->GetService(serviceRef));
   unsigned int size = service->GetNumberOfPlanePositions();
   unsigned int id = service->AddNewPlanePosition(plane, positionEvent->GetSender()->GetSliceNavigationController()->GetSlice()->GetPos());
 
   mitk::PlanarCircle::Pointer contourMarker = mitk::PlanarCircle::New();
   contourMarker->SetGeometry2D( const_cast<Geometry2D*>(plane));
 
   std::stringstream markerStream;
   mitk::DataNode* workingNode (m_ToolManager->GetWorkingData(0));
 
   markerStream << m_Contourmarkername ;
   markerStream << " ";
   markerStream << id+1;
 
   DataNode::Pointer rotatedContourNode = DataNode::New();
 
   rotatedContourNode->SetData(contourMarker);
   rotatedContourNode->SetProperty( "name", StringProperty::New(markerStream.str()) );
   rotatedContourNode->SetProperty( "isContourMarker", BoolProperty::New(true));
   rotatedContourNode->SetBoolProperty( "PlanarFigureInitializedWindow", true, positionEvent->GetSender() );
   rotatedContourNode->SetProperty( "includeInBoundingBox", BoolProperty::New(false));
   rotatedContourNode->SetProperty( "helper object", mitk::BoolProperty::New(!m_ShowMarkerNodes));
 
   if (plane)
   {
 
     if ( id ==  size )
     {
       m_ToolManager->GetDataStorage()->Add(rotatedContourNode, workingNode);
     }
     else
     {
         mitk::NodePredicateProperty::Pointer isMarker = mitk::NodePredicateProperty::New("isContourMarker", mitk::BoolProperty::New(true));
 
         mitk::DataStorage::SetOfObjects::ConstPointer markers = m_ToolManager->GetDataStorage()->GetDerivations(workingNode,isMarker);
 
         for ( mitk::DataStorage::SetOfObjects::const_iterator iter = markers->begin();
           iter != markers->end();
           ++iter)
         {
             std::string nodeName = (*iter)->GetName();
             unsigned int t = nodeName.find_last_of(" ");
             unsigned int markerId = atof(nodeName.substr(t+1).c_str())-1;
             if(id == markerId)
             {
                 return id;
             }
         }
         m_ToolManager->GetDataStorage()->Add(rotatedContourNode, workingNode);
     }
   }
   return id;
 }
 
 void mitk::SegTool2D::InteractiveSegmentationBugMessage( const std::string& message )
 {
   MITK_ERROR << "********************************************************************************" << std::endl
     << " " << message << std::endl
     << "********************************************************************************" << std::endl
     << "  " << std::endl
     << " If your image is rotated or the 2D views don't really contain the patient image, try to press the button next to the image selection. " << std::endl
     << "  " << std::endl
     << " Please file a BUG REPORT: " << std::endl
     << " http://bugs.mitk.org" << std::endl
     << " Contain the following information:" << std::endl
     << "  - What image were you working on?" << std::endl
     << "  - Which region of the image?" << std::endl
     << "  - Which tool did you use?" << std::endl
     << "  - What did you do?" << std::endl
     << "  - What happened (not)? What did you expect?" << std::endl;
 }