2nd Workshop - Trento Proton Beam Line Facility

17 Jun 2024, 14:00 → 18 Jun 2024, 14:00 Europe/Rome

Aula Kessler (Trento)

Francesco Tommasino (Unitn - TIFPA)

Three years after the first edition, we are happy to invite you to the 2nd Workshop “Trento Proton Beam Line Facility”. While the first edition was organized remotely in 2020 due to pandemic restrictions, we are now planning for a two-days meeting in Trento.

The workshop will be dedicated to past and current Users of the Trento facility, which is part of the Trento Proton Therapy Center (APSS, Azienda Provinciale per i Servizi Sanitari), and aims at:

• Collecting experiences by the groups who performed experiments in Trento in the last years.
• Giving the chance to have a common overview on the activities that can be currently performed in the facility.
• Encouraging collaborations and sinergies among groups with common research interests. 
• Being the occasion for a discussion on potential improvements of the facility, which could further enlarge the spectrum of users and experimental activities.
• Report and discuss on the recent scientific developments in the fields of detector development (for medical, space and other scientific applications), radiobiology, radiation hardness.

The meeting is scheduled for June 17-18th 2024. Registration and abstract submission is now open. Further information can be found in the dedicated sections (left menu).

 

TIFPA_LOGO_Color-2.png

Monday, 17 June

14:30 → 15:00 Opening: Welcome Session

Convener: Francesco Tommasino (Physics department, University of Trento and TIFPA)

14:30 Opening address

Speaker: Francesco Pederiva (TIFP)

14:40 Trento Proton Therapy Center

Speaker: Frank Lohr (APSS - Unitn)

14:50 CSN 5 perspectives

Speaker: Alberto Quaranta (TIFPA - University of Trento)

15:00 → 16:00 Detectors: First Session

15:00 Characterization of thin silicon detectors for applications in conventional and flash irradiations

Speaker: Francesco Pennazio (Istituto Nazionale di Fisica Nucleare)

Pennazio slides Trento 2024 Public.pdf

15:12 Dosimetric characterization of ultra-high dose rate proton beams for FLASH radiotherapy using calorimetry

Speaker: Giuliana Giuseppina Milluzzo (Istituto Nazionale di Fisica Nucleare)

15:24 Beam and treatment monitoring in FLASH and CONV regimes for PT applications

Speaker: Giacomo Traini (Istituto Nazionale di Fisica Nucleare)

Trento_workshop_tifpa.pdf

15:36 Towards real-time dose control during cancer radiation therapies based on full-organic wearable dosimeter

Speaker: Laura Basiricò (Istituto Nazionale di Fisica Nucleare)

15:48 Microdosimetry at the proton therapy facility of Trento

Speaker: Anna Bianchi (Istituto Nazionale di Fisica Nucleare)

16:00 → 16:20 Coffee Break

16:20 → 17:05 Radiation Hardness

16:20 Proton-induced Radiation Damage Effects on Silicon Photomultipliers for HEP and space experiments

Speakers: Fabio Acerbi (FBK, TIFPA), fabio acerbi (FBK)

16:32 xRadiation damage and mitigation strategies for the SiPM of the ePIC-dRICH detector at the EIC

Speaker: Dr Nicola Funicello (Istituto Nazionale di Fisica Nucleare)

16:44 Study of SEU effects in readout circuits of silicon micro-strips detectors developed in 110 nm UMC technology.

Speaker: Daniela Calvo (Istituto Nazionale di Fisica Nucleare)

17:05 → 18:15 Radiobiology: First Session

17:05 p21: a new player in colon cancer cell radioresistance.

Speaker: Alessandra Bisio (Istituto Nazionale di Fisica Nucleare)

17:17 The effect of particle therapy on tumour angiogenesis

Speaker: Charnay Cunningham

17:29 Microtubules as IR target

Speaker: Simonetta Croci (Istituto Nazionale di Fisica Nucleare)

17:41 MGM: development and validation of a microdosimetric genomic model to predict radiation-induced mutation in space

Speaker: Lorenzo Manganaro (TO)

17:53 Continuous Microdosimetric Photon Isoeffective Dose Model: experimental measurements

This study presents the outcomes of combined radiobiological-microdosimetric experiments conducted in the same selected positions along the profile of a Spread-Out Bragg Peak (SOBP). The aim was to obtain the necessary parameters for a novel microdosimetric model for computing photon isoeffective doses in proton therapy [1-5]. This model, named Continuous Microdosimetric Photon Isoeffective Dose Model, depends on the first 3 moments of the lineal energy of microdosimetric spectra. In addition, these quantities are closely linked to Modified Linear Quadratic survival parameters that will be obtained from radiobiological experiments.

In this context, microdosimetric spectra measurements were conducted using two different Mini-TEPC microdosimeters in collaboration with Valeria Conte et al. (INFN). The sensitive volume of each microdosimeter was positioned at five predetermined measuring positions within solid water blocks, employing SOBP produced by a 148 MeV proton beam in the experimental room of the Trento Proton Therapy Centre.

Cell survival curves were generated at the same five designated positions, employing the same experimental setup used in microdosimetric experiments. These curves were constructed using doses of 0.5, 1.5, 3.5, 6, and 8 Gy, considering two different cell lines, JHU-11 and H460.

Radiobiological experiments involved the irradiation of two cell culture flasks at the same time positioned in the same way as the sensitive volume of the microdosimeter, so that they were exposed to a similar radiation field.

The model depends also on radiobiological parameters for a reference photon radiation. Survival curve for both cell lines were obtained using photons from the Xstrahl RS225 X-ray research irradiator available at TIFPA, considering the following doses: 0.5, 1.5, 3.5, 6, and 8 Gy.

[1] González et al. The photon isoeffective dose in BNCT. Radiat.Res.178.6(2012):609-621.
[2] González et al. Photon isoeffective dose for cancer treatment with mixed field radiation based on dose–response assessment from human and an animal model: clinical application to BNCT for head & neck cancer. Phys.Med.Biol.62.20(2017):7938.
[3] Perotti Bernardini et al. Comparison of Photon Isoeffective Dose Models Based on In Vitro and In Vivo Radiobiological Experiments for Head & Neck Cancer Treated with BNCT. Radiat.Res.(2022):134-144.
[4] Valeriano et al. (2023). A new formalism in hadron therapy for dose calculations in photon equivalent units. PTCOG Conference.
[5] Postuma et al. Using the photon isoeffective dose formalism to compare and combine BNCT and CIRT in a head & neck tumour. Sci.Rep.14.1(2024):418.

Speaker: Lucrecia Mariel Valeriano (INFN-TIFPA)

18:15 → 19:30 Aperitif - Get together

Tuesday, 18 June

09:15 → 10:00 Facilities

09:15 Overview of experimental research at the proton therapy facility Dresden

Speaker: Jörg Pawelke (OncoRay Dresden (Germany))

09:35 The CNAO center and experimental facility: development and upgrades

Speaker: Marco Pullia (CNAO)

10:00 → 11:25 Radiobiology: Second Session

10:00 FLASH understanding: the radiobiology program of FRIDA-WP1

Speaker: Emanuele Scifoni (INFN, Trento Institute for Fundamental Physics and Applications (TIFPA), Povo, TN, Italy)

10:12 Validation of Trento’s Proton Centre for FLASH Radiotherapy: A Comparative Analysis, Insight from Zebrafish

Speaker: Alessia Faggian (Istituto Nazionale di Fisica Nucleare)

10:24 A proton minibeam setup in the TPBL and the MIRO project

Minibeam irradiation is seen as a new frontier for exploiting the advantages of proton beams, as well as other types of radiation, towards increasing the therapeutic ratio on clinical treatments. In this context a novel INFN project has been recently launched called MIRO - Minibeam Radiation, dedicated to the investigation of beam design and radiobiological effectiveness of electron and proton minibeam irradiations. The first part of this project carried on at the Trento proton beam Laboratory (TEPBL) was the setup of a dedicated line for irradiation through a specific collimator, which, being able to serve both for protons (70 MeV) and electrons could allow a link between the local investigations and those performed with electrons in Pisa. This first setup was firstly characterised by extensive simulations and then used for experimental measurements through EBT films. The agreement between simulation and measurements was very promising and it was possible realised a peak to valley dose ratio (PVDR) uin the setup, larger of 3.5, uo to 5 mm depth after the collimator, thus allowing in principle irradiation of biological samples in the range relevant to mini beam radiobiology research. Further design of more opimized collimators is also proposed, through dedicated simulations.

Speaker: Emanuele Scifoni (Istituto Nazionale di Fisica Nucleare)

10:40 Coffee Break

11:00 Comparative study of the effects induced by innovative radiotherapy treatments in zebrafish

Speaker: Gaia Pucci (Institute of Molecular Bioimaging and Physiology–National Research Council (IBFM-CNR), Cefalù, Italy)

11:12 Activation of the p53 pathway in combination with photon or proton irradiation for the treatment of brain tumours

Speaker: Xanthene Miles

11:25 → 12:25 Detectors: Second Session

11:25 The Proton Radiography experiment

Speaker: Carlo Civinini (Istituto Nazionale di Fisica Nucleare)

Trento_Workshop_2024-Civinini.pdf

11:37 Characterization of FOOT silicon microstrip detectors with protons.

Speaker: Leonello Servoli (Istituto Nazionale di Fisica Nucleare)

MSD_at_Trento-APSS.pdf

11:49 Test of amorphous silicon detectors on the Trento Proton Beam Line

Speaker: Leonello Servoli (Istituto Nazionale di Fisica Nucleare)

HASPIDE_at_Trento_APSS.pdf

12:01 The beam test journey of the HEPD-02 detector at Trento Proton therapy center

Speaker: Ester Ricci (Istituto Nazionale di Fisica Nucleare)

12:13 Evaluating the Reliability of AI Accelerators with Proton Experiments

Speaker: Bruno Loreiro Coelho (University of Trento)

12:30 → 13:00 Closure: Final remarks

13:00 → 14:00 Light Lunch