Impact of SBRT fractionation in hypoxia dose painting - Accounting for heterogeneous and dynamic tumor oxygenation

Emely Kjellsson Lindblom; Ana Ureba; Alexandru Dasu; Peter Wersäll; Aniek J G Even; Wouter van Elmpt; Philippe Lambin; Iuliana Toma-Dasu

doi:10.1002/mp.13514

Impact of SBRT fractionation in hypoxia dose painting - Accounting for heterogeneous and dynamic tumor oxygenation

Med Phys. 2019 May;46(5):2512-2521. doi: 10.1002/mp.13514. Epub 2019 Apr 14.

Authors

Emely Kjellsson Lindblom¹, Ana Ureba¹, Alexandru Dasu², Peter Wersäll³, Aniek J G Even⁴, Wouter van Elmpt⁴, Philippe Lambin⁴, Iuliana Toma-Dasu^{1

5}

Affiliations

¹ Medical Radiation Physics, Department of Physics, Stockholm University, Stockholm, S-17176, Sweden.
² The Skandion Clinic, Uppsala, S-75237, Sweden.
³ Department of Oncology, Karolinska University Hospital, Stockholm, S-17176, Sweden.
⁴ Department of Radiation Oncology (MAASTRO), GROW-School for Oncology and Developmental Biology, Maastricht University Medical Center, Maastricht, 6229, The Netherlands.
⁵ Medical Radiation Physics, Department of Oncology and Pathology, Karolinska Institutet, Stockholm, S-17176, Sweden.

PMID: 30924937
DOI: 10.1002/mp.13514

Abstract

Purpose: Tumor hypoxia, often found in nonsmall cell lung cancer (NSCLC), implies an increased resistance to radiotherapy. Pretreatment assessment of tumor oxygenation is, therefore, warranted in these patients, as functional imaging of hypoxia could be used as a basis for dose painting. This study aimed at investigating the feasibility of using a method for calculating the dose required in hypoxic subvolumes segmented on ¹⁸ F-HX4 positron emission tomography (PET) imaging of NSCLC.

Methods: Positron emission tomography imaging data based on the hypoxia tracer ¹⁸ F-HX4 of 19 NSCLC patients were included in the study. Normalized tracer uptake was converted to oxygen partial pressure (pO₂ ) and hypoxic target volumes (HTVs) were segmented using a threshold of 10 mmHg. Uniform doses required to overcome the hypoxic resistance in the target volumes were calculated based on a previously proposed method taking into account the effect of interfraction reoxygenation, for fractionation schedules ranging from extremely hypofractionated stereotactic body radiotherapy (SBRT) to conventionally fractionated radiotherapy.

Results: Gross target volumes ranged between 6.2 and 859.6 cm³ , and the hypoxic fraction < 10 mmHg between 1.2% and 72.4%. The calculated doses for overcoming the resistance of cells in the HTVs were comparable to those currently prescribed in clinical practice as well as those previously tested in feasibility studies on dose escalation in NSCLC. Depending on the size of the HTV and the distribution of pO₂ , HTV doses were calculated as 43.6-48.4 Gy for a three-fraction schedule, 51.7-57.6 Gy for five fractions, and 59.5-66.4 Gy for eight fractions. For patients in whom the HTV pO₂ distribution was more favorable, a lower dose was required despite a bigger volume. Tumor control probability was lower for single-fraction schedules, while higher levels of tumor control probability were found for schedules employing several fractions.

Conclusions: The method to account for heterogeneous and dynamic hypoxia in target volume segmentation and dose prescription based on ¹⁸ F-HX4-PET imaging appears feasible in NSCLC patients. The distribution of oxygen partial pressure within HTV could impact the required prescribed dose more than the size of the volume.

Keywords: dose painting; fractionation; hypoxia.

MeSH terms

Carcinoma, Non-Small-Cell Lung / diagnostic imaging
Carcinoma, Non-Small-Cell Lung / metabolism
Carcinoma, Non-Small-Cell Lung / pathology
Carcinoma, Non-Small-Cell Lung / radiotherapy*
Dose Fractionation, Radiation*
Humans
Lung Neoplasms / diagnostic imaging
Lung Neoplasms / metabolism
Lung Neoplasms / pathology
Lung Neoplasms / radiotherapy*
Oxygen / metabolism*
Positron-Emission Tomography
Radiosurgery*
Tumor Hypoxia / radiation effects*

Substances

Oxygen