Copenhagen, Denmark
Onsite/Online

ESTRO 2022

Session Item

RTT treatment planning, OAR and target definitions
Poster (digital)
RTT
ANALYSIS OF VASCULAR AND CIRCULAR BLOOD IN RADIATION TREATMENT PLANNING: TECHNOLOGICAL OPTIONS
ROSA MARIA MEIRIÑO, Spain
PO-1885

Abstract

ANALYSIS OF VASCULAR AND CIRCULAR BLOOD IN RADIATION TREATMENT PLANNING: TECHNOLOGICAL OPTIONS
Authors:

ROSA MARIA MEIRIÑO1, Felipe Calvo Manuel1, Javier Burguete2, Javier Serrano Andreu1, Javier Aristu1, Diego Azcona3, Mauricio Cambeiro1, Marta Vidorreta4, Javier Pascau5, Jose Miguel Delgado3, Alberto Alonso6

1Clínica Universidad de Navarra, Oncología Radioterápica, Madrid, Spain; 2Universidad de Navarra, Departamento de Matemática y Física Aplicada, Pamplona, Spain; 3Clínica Universidad de Navarra, Radiofísica Hospitalaria, Madrid, Spain; 4Siemens Healthcare, MR Clinical Scientist, Madrid, Spain; 5Universidad Carlos III, Ingeniería Biomédica, Madrid, Spain; 6Clínica Universidad de Navarra, Radiología, Madrid, Spain

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Purpose or Objective


Evaluate the possibility of implementing segmentation the vascular tree in treatment planning of Radiotherapy using new imaging methods such as CT-Body perfusion that allows visualization and segmentation of the arterial vessels or the MRI -4D Flow sequences that allow the quantification of vascular blood. 

Material and Methods


CT-Body Perfusion

Between April 2019 and March 2020, 20 patients treated with a radiotherapy component underwent CT-Body-Perfusion, acquiring multiple series, in order to obtain images of the arterial and venous phases after a 1st bolus of contrast. A second static CT is performed after the administration of a second bolus of slow contrast to visualize the entire vascular tree.

 

MRI-4D flow

Between March 2021 and July 2021 in 31 patients treated with a radiotherapy component, series of MRI-4D flow images were performed in the context of treatment planning in order to visualize the entire vascular tree, to avoid artifacts in the images are the product of the patient's breathing, gating techniques have been used in the thoracic and abdominal locations.

 

Processing was performed using the SyngoVia system in the CT body perfusion module or MM-reading. Reconstruction of the sequences were exported to RayStation TPS for vessels automatic segmentation. 

Results


CT-Body Perfusion

Approximately 27 to 40 in total series are made in each study with Image sequences every 1.5 seconds. The proportion of supra-infradiaphragmatic locations was 60/40.

The exam requires an approximate time of 20 to 30 minutes.

 

MRI-4D flow

As a result of acquiring 4D flow images, 2 different types of images are obtained, an anatomical image and a velocity-coded image. The temporal resolution of 41-54 ms, the spatial resolution of 1-1.7 mm3 and VENC = 20-70 cm/s. Approximately 150 slices are made in each series. The supra-infradiaphragmatic ratio was 62/38.

Adding the 4D flow sequence to the clinical protocol increases the scan time by 10-20 minutes.

 

 

Conclusion


The inclusion of advanced imaging techniques would allow the design of vascular structures such as OAR in Radiotherapy treatments in order to develop strategies to predict and, to a certain extent, prevent RT-induced vascular and blood damage. MRI's intrinsic sensitivity to movement offers the unique ability to acquire blood flow simultaneously with the anatomical data within a single measurement and makes it possible to implement vascular segmentation without subjecting the patient to greater exposure to radiation and in a reasonable time.