Dose painting by numbers - do the practical limitations of the technique decrease or increase the probability of controlling tumours?

Daşu, Alexandru; Toma-Daşu, Iuliana

doi:10.1007/978-3-642-29305-4_455

Cited by 4 publications

(1 citation statement)

References 14 publications

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“…Furthermore, the limited spatial resolution of imaging methods could lead to poor rendering of the small hypoxic regions [76] that would translate into an underestimation of their radiosensitivity. However, this might be less of a problem for rapid interfraction reoxygenation that might ensure the success of dose painting techniques that do not take into account the microscale heterogeneity of hypoxia [85]. …”

Section: Tumour Oxygenation and Treatment Modellingmentioning

confidence: 99%

Modelling Tumour Oxygenation, Reoxygenation and Implications on Treatment Outcome

Toma-Daşu

Daşu

2013

Computational and Mathematical Methods in Medicine

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Oxygenation is an important component of the tumour microenvironment, having a significant impact on the progression and management of cancer. Theoretical determination of tissue oxygenation through simulations of the oxygen transport process is a powerful tool to characterise the spatial distribution of oxygen on the microscopic scale and its dynamics and to study its impact on the response to radiation. Accurate modelling of tumour oxygenation must take into account important aspects that are specific to tumours, making the quantitative characterisation of oxygenation rather difficult. This paper aims to discuss the important aspects of modelling tumour oxygenation, reoxygenation, and implications for treatment.

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Section: Tumour Oxygenation and Treatment Modellingmentioning

confidence: 99%

Modelling Tumour Oxygenation, Reoxygenation and Implications on Treatment Outcome

Toma-Daşu

Daşu

2013

Computational and Mathematical Methods in Medicine

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Quantitative Hypoxia Imaging for Treatment Planning of Radiotherapy

Toma-Daşu

Daşu

2014

Advances in Experimental Medicine and Biology

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Tumour oxygenation is an important determinant of radiotherapy outcome as it could modulate cellular radiation sensitivity. Advanced PET imaging able to characterise this microenvironmental aspect in vivo might be used to devise counteracting therapies as it could provide information on the severity and the spatial distribution of the hypoxic regions. This study reviews the advantages and limitations of PET for imaging and quantifying tumour hypoxia and proposes a novel approach to obtain absolute levels of hypoxia from PET images through the use of EPR oximetry. This would offer a significant advantage over proposals based on empirical conversions of the intensities in the PET images to relative radiosensitivities. Thus, tumour hypoxia must be taken into account at the stage of treatment planning for photons and particle therapy by accounting for its extent and severity through the use of PET imaging combined with absolute EPR measurements.

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Assessment of the Probability of Tumour Control for Prescribed Doses Based on Imaging of Oxygen Partial Pressure

Ureba¹,

Lindblom

Toma-Daşu

et al. 2021

Advances in Experimental Medicine and Biology

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Dose painting by numbers - do the practical limitations of the technique decrease or increase the probability of controlling tumours?

Cited by 4 publications

References 14 publications

Modelling Tumour Oxygenation, Reoxygenation and Implications on Treatment Outcome

Modelling Tumour Oxygenation, Reoxygenation and Implications on Treatment Outcome

Quantitative Hypoxia Imaging for Treatment Planning of Radiotherapy

Assessment of the Probability of Tumour Control for Prescribed Doses Based on Imaging of Oxygen Partial Pressure

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