Ottimizzazione di un sistema di calcolo Voxel dosimetry e implementazione di grandezze radiobiologiche per MRT

Il presente lavoro di tesi nasce in seguito all’esperienza di tirocinio svolta presso l’Arcispedale Santa Maria Nuova di Reggio Emilia. Fulcro di questo lavoro è lo sviluppo di un sistema di pianificazione della dose per il trattamento dei pazienti sottoposti a Molecular Radionuclide Therapy (MRT). Presso tale struttura ospedaliera è già stato sviluppato uno strumento che si appoggia all’ambiente di lavoro Matlab per il calcolo dosimetrico. Tale programma è chiamato VoxelMed. Si tratta di uno strumento di calcolo che lavora al così detto voxel-level, tecnica di sviluppo recente che permette il calcolo della dose assorbita all’interno di un paziente in modo più dettagliato rispetto ai metodi di calcolo basati unicamente sulla stima media per organo, tipicamente impiegati in dosimetria tradizionale. Parte del lavoro di tesi consiste nell’implementare nuove modalità di calcolo ed aggiungere ulteriori accorgimenti all’attuale versione di VoxelMed. In VoxelMed è stata poi integrata ex-novo una componente di calcolo di misure radiobiologiche, in particolare della BED. La dose assorbita non è infatti un parametro sufficiente per valutare gli effetti della radiazione sui tessuti, a parità di tipo ed energia della radiazione gli effetti possono essere molto variabili. La BED è il parametro che tiene conto della risposta del tessuto sano o cancerogeno alla radiazione. Parte del lavoro è stato svolto sperimentalmente, tramite misure con fantocci acquisiti o preparati ad hoc. In particolare si sono utilizzati diverse tipologie di fantocci, per effettuare protocolli di calibrazione dei sistemi di acquisizione, misure di curve di effetto di volume parziale e test finali di verifica. Per un ulteriore verifica delle prestazioni di calcolo si sono effettuate misurazioni su un gruppo di pazienti e si sono confrontati i risultati con quelli ottenuti dal software maggiormente utilizzato nella pratica clinica, OLINDA/EXM.

Implementation of a VLSI amplifier interfaced with biomedical sensors for ultra wide band data transmission

This thesis presents a CMOS Amplifier with High Common Mode rejection designed in UMC 130nm technology. The goal is to achieve a high amplification factor for a wide range of biological signals (with frequencies in the range of 10Hz-1KHz) and to reject the common-mode noise signal. It is here presented a Data Acquisition System, composed of a Delta-Sigma-like Modulator and an antenna, that is the core of a portable low-complexity radio system; the amplifier is designed in order to interface the data acquisition system with a sensor that acquires the electrical signal. The Modulator asynchronously acquires and samples human muscle activity, by sending a Quasi-Digital pattern that encodes the acquired signal. There is only a minor loss of information translating the muscle activity using this pattern, compared to an encoding technique which uses astandard digital signal via Impulse-Radio Ultra-Wide Band (IR-UWB). The biological signals, needed for Electromyographic analysis, have an amplitude of 10-100μV and need to be highly amplified and separated from the overwhelming 50mV common mode noise signal. Various tests of the firmness of the concept are presented, as well the proof that the design works even with different sensors, such as Radiation measurement for Dosimetry studies.

Procedural and dosimetric aspects in peripheral angiography using CO2 as contrast medium

Lo scopo di questa tesi è lo studio degli aspetti procedurali e dosimetrici in angiografie periferiche che utilizzano la CO2 come mezzo di contrasto. La tecnica angiografica consiste nell’imaging radiologico di vasi sanguigni tramite l’iniezione di un mezzo di contrasto, e il suo uso è in costante incremento a causa dell’aumento di pazienti con malattie vascolari. I mezzi di contrasto iodati sono i più comunemente utilizzati e permettono di ottenere immagini di ottima qualità, ma presentano il limite di una elevata nefrotossicità. La CO2 è considerata un’interessante alternativa al mezzo iodato, per la sua acclarata biocompatibilità, soprattutto per pazienti con elevati fattori di rischio (diabete e/o insufficienza renale). Il suo utilizzo presenta comunque alcuni aspetti problematici, dovuti allo stato gassoso e al basso contrasto intrinseco rispetto alla soluzione iodata. Per quest’ultimo motivo si ritiene generalmente che l’utilizzo della CO2 comporti un aumento di dose rispetto ai mezzi di contrasto tradizionali. Il nostro studio, effettuato su diversi apparati radiologici, ha dimostrato che i parametri di emissione radiologica sono gli stessi per i protocolli di angiografia tradizionale, con iodio, e quelli che utilizzano CO2. Questa evidenza suggerisce che i protocolli CO2 operino solo sul trattamento delle immagini ottenute e non sulla modalità di acquisizione, e dal punto di vista dosimetrico l’angiografia con CO2 è riconducibile all’angiografia tradizionale. L’unico fattore che potrebbe portare a un effettivo incremento di dose al paziente è un allungamento dei tempi di scopia e di procedura, che andrebbe verificato con una campagna di misure in ambito clinico. Sulla base della stessa evidenza, si ritiene che la visualizzazione della CO2 possa essere ulteriormente migliorata attraverso l’ottimizzazione dei parametri di emissione radiologica (kVp, frame rate e durata degli impulsi) attualmente predisposti per l’uso di mezzi di contrasto iodati.

Novel materials for direct X-ray detectors based on semiconducting organic polymers

Conventional inorganic materials for x-ray radiation sensors suffer from several drawbacks, including their inability to cover large curved areas, me- chanical sti ffness, lack of tissue-equivalence and toxicity. Semiconducting organic polymers represent an alternative and have been employed as di- rect photoconversion material in organic diodes. In contrast to inorganic detector materials, polymers allow low-cost and large area fabrication by sol- vent based methods. In addition their processing is compliant with fexible low-temperature substrates. Flexible and large-area detectors are needed for dosimetry in medical radiotherapy and security applications. The objective of my thesis is to achieve optimized organic polymer diodes for fexible, di- rect x-ray detectors. To this end polymer diodes based on two different semi- conducting polymers, polyvinylcarbazole (PVK) and poly(9,9-dioctyluorene) (PFO) have been fabricated. The diodes show state-of-the-art rectifying be- haviour and hole transport mobilities comparable to reference materials. In order to improve the X-ray stopping power, high-Z nanoparticle Bi2O3 or WO3 where added to realize a polymer-nanoparticle composite with opti- mized properities. X-ray detector characterization resulted in sensitivties of up to 14 uC/Gy/cm2 for PVK when diodes were operated in reverse. Addition of nanoparticles could further improve the performance and a maximum sensitivy of 19 uC/Gy/cm2 was obtained for the PFO diodes. Compared to the pure PFO diode this corresponds to a five-fold increase and thus highlights the potentiality of nanoparticles for polymer detector design. In- terestingly the pure polymer diodes showed an order of magnitude increase in sensitivity when operated in forward regime. The increase was attributed to a different detection mechanism based on the modulation of the diodes conductivity.

Applications of advanced and dual energy computed tomography in proton therapy

This thesis focuses on advanced reconstruction methods and Dual Energy (DE) Computed Tomography (CT) applications for proton therapy, aiming at improving patient positioning and investigating approaches to deal with metal artifacts. To tackle the first goal, an algorithm for post-processing input DE images has been developed. The outputs are tumor- and bone-canceled images, which help in recognising structures in patient body. We proved that positioning error is substantially reduced using contrast enhanced images, thus suggesting the potential of such application. If positioning plays a key role in the delivery, even more important is the quality of planning CT. For that, modern CT scanners offer possibility to tackle challenging cases, like treatment of tumors close to metal implants. Possible approaches for dealing with artifacts introduced by such rods have been investigated experimentally at Paul Scherrer Institut (Switzerland), simulating several treatment plans on an anthropomorphic phantom. In particular, we examined the cases in which none, manual or Iterative Metal Artifact Reduction (iMAR) algorithm were used to correct the artifacts, using both Filtered Back Projection and Sinogram Affirmed Iterative Reconstruction as image reconstruction techniques. Moreover, direct stopping power calculation from DE images with iMAR has also been considered as alternative approach. Delivered dose measured with Gafchromic EBT3 films was compared with the one calculated in Treatment Planning System. Residual positioning errors, daily machine dependent uncertainties and film quenching have been taken into account in the analyses. Although plans with multiple fields seemed more robust than single field, results showed in general better agreement between prescribed and delivered dose when using iMAR, especially if combined with DE approach. Thus, we proved the potential of these advanced algorithms in improving dosimetry for plans in presence of metal implants.

Conceptual design of the integral measurement system of the radiation dose of the fuel elements for the ALFRED reactor.

Conceptual design of the integral measurement system of the radiation dose of the fuel elements for the ALFRED reactor.

Study of high-quality ALD gate dielectrics in radiation sensitive oxide field effect transistors

Radiation dosimetry is crucial in many fields, where the exposure of ionizing radiation must be precisely controlled to avoid health and environmental safety issues. Radiotherapy and radioprotection are two examples in which fast and reliable detectors are needed. Compact and large area wearable detectors are being developed to address real-life radiation dosimetry applications, their ideal properties include flexibility, lightness, and low-cost. This thesis contributed to the development of Radiation sensitive OXide Field Effect Transistors (ROXFETs), which are detectors able to provide fast and real-time radiation read out. ROXFETs are based on thin film transistors fabricated with high-mobility amorphous oxide semiconductor, making them compatible with large area, flexible, and low cost production over plastic substrates. The gate dielectric material has high dielectric constant and high atomic number, which results in high performances and high radiation sensitivity, respectively. The aim of this work was to establish a stable and reliable fabrication process for ROXFETs made with atomic layer deposited gate dielectric. A study on the effect of gate dielectric materials was performed, focusing the attention on the properties of the dielectric-semiconductor interface. Single and multi layer dielectric structures were compared during this work. Furthermore, the effect of annealing temperature was studied. The device performances were tested to understand the underlying physical processes. In this way, it was possible to determine a reliable fabrication procedure and an optimal structure for ROXFETs. An outstanding sensitivity of (65±3)V/Gy was measured in detectors with a bi-layer Ta₂O₅-Al₂O₃ gate dielectric with low temperature annealing performed at 180°C.

Dosimetric optimization of CT protocols for the preoperative planning of hip arthroplasty

Radiation dose in x-ray computed tomography (CT) has become a topic of great interest due to the increasing number of CT examinations performed worldwide. In fact, CT scans are responsible of significant doses delivered to the patients, much larger than the doses due to the most common radiographic procedures. This thesis work, carried out at the Laboratory of Medical Technology (LTM) of the Rizzoli Orthopaedic Institute (IOR, Bologna), focuses on two primary objectives: the dosimetric characterization of the tomograph present at the IOR and the optimization of the clinical protocol for hip arthroplasty. In particular, after having verified the reliability of the dose estimates provided by the system, we compared the estimates of the doses delivered to 10 patients undergoing CT examination for the pre-operative planning of hip replacement with the Diagnostic Reference Level (DRL) for an osseous pelvis examination. Out of 10 patients considered, only for 3 of them the doses were lower than the DRL. Therefore, the necessity to optimize the clinical protocol emerged. This optimization was investigated using a human femur from a cadaver. Quantitative analysis and comparison of 3D reconstructions were made, after having performed manual segmentation of the femur from different CT acquisitions. Dosimetric simulations of the CT acquisitions on the femur were also made and associated to the accuracy of the 3D reconstructions, to analyse the optimal combination of CT acquisition parameters. The study showed that protocol optimization both in terms of Hausdorff distance and in terms of effective dose (ED) to the patient may be realized simply by modifying the value of the pitch in the protocol, by choosing between 0.98 and 1.37.

Characterization of a prototype for cone beam breast computed tomography

The project aims to experiment the Cone Beam Breast Computed Tomography technique using a standard digital mammography system. The work is focused on the definition of a protocol of quality measurements for the pre-clinical evaluation of the machine. The paper is developed in two parts. The first is specifically concerned with the methods used to define the image quality and dosimetry aspects specific for digital mammography devices. A complete characterization of the system has been performed according to the applicable IEC standards to assure the performances of the equipment and define the quality levels. Due to the lack of a quality control protocol dedicated to CBBCT mammography scanner, a new equivalent test procedure has been proposed. The second part of the paper is focused on the evaluation, through quantitative and visual analyzes, of the CBCT exam feasibility in the hardware and software conditions currently proposed by IMS Giotto. The prototype was in fact developed differing from the technical choices of competing companies and developed for a different intended use. The main difference with respect to the existing breast CT scanners is the possibility of performing on the same system the CBBCT scanning but also all the mammographic techniques. In this thesis, we aim to assess whether, in the current setup, considering a dosimetric range very close to that used in the clinic, the tests produce results that can be considered acceptable or at least indicative of the feasibility of the entire project from a commercial point of view. For this purpose, the final reconstruction images, obtained by two previously developed software, are analyzed.