The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review

The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review

Glioblastoma is the most aggressive and malignant primary brain tumor in adults. Despite the current state-of-the-art treatment, which consists of maximal surgical resection followed by radiation therapy, concomitant, and adjuvant chemotherapy, progression remains rapid due to aggressive tumor chara...

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Main Authors: Sam Donche, Jeroen Verhoeven, Benedicte Descamps, Julie Bolcaen, Karel Deblaere, Tom Boterberg, Caroline Van den Broecke, Christian Vanhove, Ingeborg Goethals
Format: Article
Language:English
Published: Frontiers Media S.A. 2019-01-01
Series:Frontiers in Medicine
Subjects:
PET
radiation therapy
laboratory animals
dose painting
glioblastoma
tumor heterogeneity
Online Access:https://www.frontiersin.org/article/10.3389/fmed.2019.00005/full
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spelling doaj-ab72f42ef9564cdaa0d5c47f313a245e2020-11-25T00:42:12ZengFrontiers Media S.A.Frontiers in Medicine2296-858X2019-01-01610.3389/fmed.2019.00005432710The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini ReviewSam Donche0Jeroen Verhoeven1Benedicte Descamps2Julie Bolcaen3Karel Deblaere4Tom Boterberg5Caroline Van den Broecke6Christian Vanhove7Ingeborg Goethals8Department of Radiology and Nuclear Medicine, Ghent University, Ghent, BelgiumDepartment of Pharmaceutical Analysis, Ghent University, Ghent, BelgiumDepartment of Electronics and Information Systems, Ghent University, Ghent, BelgiumDepartment of Radiology and Nuclear Medicine, Ghent University, Ghent, BelgiumDepartment of Radiology and Nuclear Medicine, Ghent University, Ghent, BelgiumDepartment of Radiation Oncology and Experimental Cancer Research, Ghent University, Ghent, BelgiumDepartment of Pathology, Ghent University, Ghent, BelgiumDepartment of Electronics and Information Systems, Ghent University, Ghent, BelgiumDepartment of Radiology and Nuclear Medicine, Ghent University, Ghent, BelgiumGlioblastoma is the most aggressive and malignant primary brain tumor in adults. Despite the current state-of-the-art treatment, which consists of maximal surgical resection followed by radiation therapy, concomitant, and adjuvant chemotherapy, progression remains rapid due to aggressive tumor characteristics. Several new therapeutic targets have been investigated using chemotherapeutics and targeted molecular drugs, however, the intrinsic resistance to induced cell death of brain cells impede the effectiveness of systemic therapies. Also, the unique immune environment of the central nervous system imposes challenges for immune-based therapeutics. Therefore, it is important to consider other approaches to treat these tumors. There is a well-known dose-response relationship for glioblastoma with increased survival with increasing doses, but this effect seems to cap around 60 Gy, due to increased toxicity to the normal brain. Currently, radiation treatment planning of glioblastoma patients relies on CT and MRI that does not visualize the heterogeneous nature of the tumor, and consequently, a homogenous dose is delivered to the entire tumor. Metabolic imaging, such as positron-emission tomography, allows to visualize the heterogeneous tumor environment. Using these metabolic imaging techniques, an approach called dose painting can be used to deliver a higher dose to the tumor regions with high malignancy and/or radiation resistance. Preclinical studies are required for evaluating the benefits of novel radiation treatment strategies, such as PET-based dose painting. The aim of this review is to give a brief overview of promising PET tracers that can be evaluated in laboratory animals to bridge the gap between PET-based dose painting in glioblastoma patients.https://www.frontiersin.org/article/10.3389/fmed.2019.00005/fullPETradiation therapylaboratory animalsdose paintingglioblastomatumor heterogeneity
collection DOAJ
language English
format Article
sources DOAJ
author Sam Donche
Jeroen Verhoeven
Benedicte Descamps
Julie Bolcaen
Karel Deblaere
Tom Boterberg
Caroline Van den Broecke
Christian Vanhove
Ingeborg Goethals
spellingShingle Sam Donche
Jeroen Verhoeven
Benedicte Descamps
Julie Bolcaen
Karel Deblaere
Tom Boterberg
Caroline Van den Broecke
Christian Vanhove
Ingeborg Goethals
The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review
Frontiers in Medicine
PET
radiation therapy
laboratory animals
dose painting
glioblastoma
tumor heterogeneity
author_facet Sam Donche
Jeroen Verhoeven
Benedicte Descamps
Julie Bolcaen
Karel Deblaere
Tom Boterberg
Caroline Van den Broecke
Christian Vanhove
Ingeborg Goethals
author_sort Sam Donche
title The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review
title_short The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review
title_full The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review
title_fullStr The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review
title_full_unstemmed The Path Toward PET-Guided Radiation Therapy for Glioblastoma in Laboratory Animals: A Mini Review
title_sort path toward pet-guided radiation therapy for glioblastoma in laboratory animals: a mini review
publisher Frontiers Media S.A.
series Frontiers in Medicine
issn 2296-858X
publishDate 2019-01-01
description Glioblastoma is the most aggressive and malignant primary brain tumor in adults. Despite the current state-of-the-art treatment, which consists of maximal surgical resection followed by radiation therapy, concomitant, and adjuvant chemotherapy, progression remains rapid due to aggressive tumor characteristics. Several new therapeutic targets have been investigated using chemotherapeutics and targeted molecular drugs, however, the intrinsic resistance to induced cell death of brain cells impede the effectiveness of systemic therapies. Also, the unique immune environment of the central nervous system imposes challenges for immune-based therapeutics. Therefore, it is important to consider other approaches to treat these tumors. There is a well-known dose-response relationship for glioblastoma with increased survival with increasing doses, but this effect seems to cap around 60 Gy, due to increased toxicity to the normal brain. Currently, radiation treatment planning of glioblastoma patients relies on CT and MRI that does not visualize the heterogeneous nature of the tumor, and consequently, a homogenous dose is delivered to the entire tumor. Metabolic imaging, such as positron-emission tomography, allows to visualize the heterogeneous tumor environment. Using these metabolic imaging techniques, an approach called dose painting can be used to deliver a higher dose to the tumor regions with high malignancy and/or radiation resistance. Preclinical studies are required for evaluating the benefits of novel radiation treatment strategies, such as PET-based dose painting. The aim of this review is to give a brief overview of promising PET tracers that can be evaluated in laboratory animals to bridge the gap between PET-based dose painting in glioblastoma patients.
topic PET
radiation therapy
laboratory animals
dose painting
glioblastoma
tumor heterogeneity
url https://www.frontiersin.org/article/10.3389/fmed.2019.00005/full
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