Dosimetric validation of a magnetic resonance image gated radiotherapy system using a motion phantom and radiochromic film.

PurposeMagnetic resonance image (MRI) guided radiotherapy enables gating directly on the target position. We present an evaluation of an MRI-guided radiotherapy system's gating performance using an MRI-compatible respiratory motion phantom and radiochromic film. Our evaluation is geared toward validation of our institution's clinical gating protocol which involves planning to a target volume formed by expanding 5 mm about the gross tumor volume (GTV) and gating based on a 3 mm window about the GTV.MethodsThe motion phantom consisted of a target rod containing high-contrast target inserts which moved in the superior-inferior direction inside a body structure containing background contrast material. The target rod was equipped with a radiochromic film insert. Treatment plans were generated for a 3 cm diameter spherical planning target volume, and delivered to the phantom at rest and in motion with and without gating. Both sinusoidal trajectories and tumor trajectories measured during MRI-guided treatments were used. Similarity of the gated dose distribution to the planned, motion-frozen, distribution was quantified using the gamma technique.ResultsWithout gating, gamma pass rates using 4%/3 mm criteria were 22-59% depending on motion trajectory. Using our clinical standard of repeated breath holds and a gating window of 3 mm with 10% target allowed outside the gating boundary, the gamma pass rate was 97.8% with 3%/3 mm gamma criteria. Using a 3 mm window and 10% allowed excursion, all of the patient tumor motion trajectories at actual speed resulting in at least 95% gamma pass rate at 4%/3 mm.ConclusionsOur results suggest that the device can be used to compensate respiratory motion using a 3 mm gating margin and 10% allowed excursion results in conjunction with repeated breath holds. Full clinical validation requires a comprehensive evaluation of tracking performance in actual patient images, outside the scope of this study

Log File-Based Dose Reconstruction to Moving Targets during Lung Stereotactic Body Radiation Therapy

Purpose: To perform film-based verification of 4D dose reconstruction to moving targets during lung stereotactic body radiation therapy (SBRT). Introduction: Current patient-specific quality assurance measures to test deliverability of plans with dynamic intensity modulation involve delivering beams to static measurement device and comparing the planned dose to measurement. However, motion-induced dose errors are not detected with static measurement. Previous studies have investigated combining machine log data with respiratory tracking to determine moving-target dose. By combining machine log data with anatomic and density information at each breathing phase from 4D-CT, intrafraction anatomical deformation due to respiration may be accounted for. However, to our knowledge, a film-based verification of dose reconstruction using machine log data, intrafraction respiratory tracking, and 4D-CT has yet to be performed. Methods: Lung SBRT plans were anonymized for 12 patients treated at our institution. Treatment plans were copied onto known geometry (programmable respiratory phantom) and dose was computed. Each SBRT plan was delivered to the phantom twice; first using 3 sec/breath (SPB), again at 6 SPB. Respiratory traces were acquired during treatment. Logfiles were acquired after treatment and partitioned according to breathing amplitude. Next, in-house code was used to import logfile beams into the treatment planning system. Dose was computed on each 4D-CT image using the imported beams and deformably accumulated. The accumulated, planned, and measured doses for each plan and breathing rate were compared using gamma analysis. Results: Gamma passing rates (GPR) (3%, 2mm, 10% threshold) of 4D dose reconstruction vs. planned dose were \u3e94% (mean 98.9% range 94.1%-100%) for all plans at each breathing rate. No significant difference was found between the 3 and 6 SPB GPRs (p=0.310). Overall, the 4D dose reconstructions were found to better agree with film measurement, within the tumor motion extent, than the treatment plan for both breathing rates (3 SPB: p=0.013, 6 SPB: p=0.017). Conclusions: Log file-based dose reconstruction was verified using film measurement for 12 lung SBRT plans delivered to a respiratory motion phantom. We showed that, given predictable phantom motion, 4D dose reconstruction resulted in significantly higher GPR compared with film than treatment plan to static geometry

A Novel Deep Learning Framework for Internal Gross Target Volume Definition from 4D Computed Tomography of Lung Cancer Patients

In this paper, we study the reliability of a novel deep learning framework for internal gross target volume (IGTV) delineation from four-dimensional computed tomography (4DCT), which is applied to patients with lung cancer treated by Stereotactic Body Radiation Therapy (SBRT). 77 patients who underwent SBRT followed by 4DCT scans were incorporated in a retrospective study. The IGTV_DL was delineated using a novel deep machine learning algorithm with a linear exhaustive optimal combination framework, for the purpose of comparison, three other IGTVs base on common methods was also delineated, we compared the relative volume difference (RVI), matching index (MI) and encompassment index (EI) for the above IGTVs. Then, multiple parameter regression analysis assesses the tumor volume and motion range as clinical influencing factors in the MI variation. Experimental results demonstrated that the deep learning algorithm with linear exhaustive optimal combination framework has a higher probability of achieving optimal MI compared with other currently widely used methods. For patients after simple breathing training by keeping the respiratory frequency in 10 BMP, the four phase combinations of 0%, 30%, 50% and 90% can be considered as a potential candidate for an optimal combination to synthesis IGTV in all respiration amplitudes

4D-CT Lung Registration and its Application for Lung Radiation Therapy

Radiation therapy has been successful in treating lung cancer patients, but its efficacy is limited by the inability to account for the respiratory motion during treatment planning and radiation dose delivery. Physics-based lung deformation models facilitate the motion computation of both tumor and local lung tissue during radiation therapy. In this dissertation, a novel method is discussed to accurately register 3D lungs across the respiratory phases from 4D-CT datasets, which facilitates the estimation of the volumetric lung deformation models. This method uses multi-level and multi-resolution optical flow registration coupled with thin plate splines (TPS), to address registration issue of inconsistent intensity across respiratory phases. It achieves higher accuracy as compared to multi-resolution optical flow registration and other commonly used registration methods. Results of validation show that the lung registration is computed with 3 mm Target Registration Error (TRE) and approximately 3 mm Inverse Consistency Error (ICE). This registration method is further implemented in GPU based real time dose delivery simulation to assist radiation therapy planning

User-initialized active contour segmentation and golden-angle real-time cardiovascular magnetic resonance enable accurate assessment of LV function in patients with sinus rhythm and arrhythmias.

BackgroundData obtained during arrhythmia is retained in real-time cardiovascular magnetic resonance (rt-CMR), but there is limited and inconsistent evidence to show that rt-CMR can accurately assess beat-to-beat variation in left ventricular (LV) function or during an arrhythmia.MethodsMulti-slice, short axis cine and real-time golden-angle radial CMR data was collected in 22 clinical patients (18 in sinus rhythm and 4 patients with arrhythmia). A user-initialized active contour segmentation (ACS) software was validated via comparison to manual segmentation on clinically accepted software. For each image in the 2D acquisitions, slice volume was calculated and global LV volumes were estimated via summation across the LV using multiple slices. Real-time imaging data was reconstructed using different image exposure times and frame rates to evaluate the effect of temporal resolution on measured function in each slice via ACS. Finally, global volumetric function of ectopic and non-ectopic beats was measured using ACS in patients with arrhythmias.ResultsACS provides global LV volume measurements that are not significantly different from manual quantification of retrospectively gated cine images in sinus rhythm patients. With an exposure time of 95.2 ms and a frame rate of > 89 frames per second, golden-angle real-time imaging accurately captures hemodynamic function over a range of patient heart rates. In four patients with frequent ectopic contractions, initial quantification of the impact of ectopic beats on hemodynamic function was demonstrated.ConclusionUser-initialized active contours and golden-angle real-time radial CMR can be used to determine time-varying LV function in patients. These methods will be very useful for the assessment of LV function in patients with frequent arrhythmias

Target localization of 3D versus 4D cone beam computed tomography in lipiodol-guided stereotactic radiotherapy of hepatocellular carcinomas

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Determination of patient-specific internal gross tumor volumes for lung cancer using four-dimensional computed tomography

<p>Abstract</p> <p>Background</p> <p>To determine the optimal approach to delineating patient-specific internal gross target volumes (IGTV) from four-dimensional (4-D) computed tomography (CT) image data sets used in the planning of radiation treatment for lung cancers.</p> <p>Methods</p> <p>We analyzed 4D-CT image data sets of 27 consecutive patients with non-small-cell lung cancer (stage I: 17, stage III: 10). The IGTV, defined to be the envelope of respiratory motion of the gross tumor volume in each 4D-CT data set was delineated manually using four techniques: (<it>1</it>) combining the gross tumor volume (GTV) contours from ten respiratory phases (IGTV_AllPhases); (<it>2</it>) combining the GTV contours from two extreme respiratory phases (0% and 50%) (IGTV_2Phases); (<it>3</it>) defining the GTV contour using the maximum intensity projection (MIP) (IGTV_MIP); and (<it>4</it>) defining the GTV contour using the MIP with modification based on visual verification of contours in individual respiratory phase (IGTV_MIP-Modified). Using the IGTV_AllPhasesas the optimum IGTV, we compared volumes, matching indices, and extent of target missing using the IGTVs based on the other three approaches.</p> <p>Results</p> <p>The IGTV_MIPand IGTV_2Phaseswere significantly smaller than the IGTV_AllPhases(<it>p </it>< 0.006 for stage I and <it>p </it>< 0.002 for stage III). However, the values of the IGTV_MIP-Modifiedwere close to those determined from IGTV_AllPhases(<it>p </it>= 0.08). IGTV_MIP-Modifiedalso matched the best with IGTV_AllPhases.</p> <p>Conclusion</p> <p>IGTV_MIPand IGTV_2Phasesunderestimate IGTVs. IGTV_MIP-Modifiedis recommended to improve IGTV delineation in lung cancer.</p

In-house Implementation and Validation of the Mid-Position CT approach for the Treatment Planning of Respiration-induced Moving Tumours in Radiotherapy for Lung and Upper abdomen cancer

Tese mestrado integrado, Engenharia Biomédica e Biofísica (Engenharia Clínica e Instrumentação Médica) Universidade de Lisboa, Faculdade de Ciências, 2022A Radioterapia é uma das modalidades principais para tratamentos de foro oncológico que visa destruir a ação proliferativa das células cancerígenas e reduzir o volume tumoral. A sua ação terapêutica através do uso de radiação ionizante tem, subjacente, a máxima de irradiar o tumor com uma elevada dose, ao mesmo tempo que os órgãos de risco (OARs) adjacentes, são tanto quanto possível protegidos. Quando um tumor se localiza no pulmão ou abdómen superior, como no fígado ou pâncreas, o seu movimento devido à respiração pode alcançar até 4 cm, especialmente na direção crânio-caudal, aumentando as incertezas relativas à posição do tumor. No Centro Clínico Champalimaud (CCC), o planeamento convencional dos tratamentos de radioterapia faz uso de uma tomografia computadorizada (CT) que é adquirida aquando da respiração livre do doente e que, por isso, apresenta geralmente artefactos que podem ser uma fonte de erro durante o planeamento. Nos casos em que o movimento do tumor é considerável, é ainda adquirida uma tomografia computadorizada quadrimensional (4DCT) que consiste entre 8 e 10 CTs que representam fases do ciclo respiratório. Posteriormente, a 4DCT é utilizada para delinear o volume interno do alvo (ITV) que engloba toda a extensão do movimento do tumor. Apesar da estratégia do ITV garantir uma adequada cobertura do volume-alvo, os OARs ficam expostos a doses de radiação desnecessárias e a um maior risco de toxicidade. Este efeito é ainda mais preocupante em tratamentos hipofracionados, onde doses mais elevadas são administradas num número reduzido de frações. Nos últimos anos têm sido desenvolvidas estratégias que visam tornar os tratamentos de radioterapia mais eficazes. Uma delas é a reconstrução de uma CT que representa a posição média do doente ao longo do ciclo respiratório (Mid-P CT). Esta estratégia resulta em volumes de tratamento menores do que a estratégia do ITV, possibilitando o aumento da dose e maior controlo tumoral local. O primeiro passo para a reconstrução do Mid-P CT é o registo deformável de imagens (DIR) entre uma das fases da respiração (uma CT da 4DCT), definida como a fase de referência, e as restantes fases. Deste processo resultam campos vetoriais deformáveis (DVF) que contém informação do deslocamento dos tecidos. Os DVFs são subsequentemente utilizados para transformar cada uma das fases da respiração para a posição média. O método do Mid-P foi implementado com sucesso no Instituto do Cancro Holandês (NKI) em 2008. Apesar dos bons resultados clínicos, o número de centros de radioterapia que utiliza esta técnica é muito reduzido. Tal deve-se, por um lado, à inexistência de soluções comerciais com esta funcionalidade e, por outro, ao esforço necessário alocar para implementar e validar soluções desenvolvidas internamente. O presente projeto teve como principal objetivo implementar a estratégia do Mid-P no CCC (Portugal). Para tal, foi otimizado um módulo – RunMidP – desenvolvido para o software 3D Slicer, que calcula o Mid-P CT e estima a amplitude do movimento do tumor e OARs com base nos DVFs. Considerando que a precisão do módulo e a qualidade de imagem do Mid-P CT devem atender os requisitos para o planeamento em radioterapia, foram realizados testes para validar o módulo. Sempre que possível, a sua performance foi comparada com outras aplicações desenvolvidas para a implementação da técnica do Mid-P, nomeadamente com um protótipo desenvolvido pela empresa Mirada Medical Ltd. (Reino Unido) – Mirada – e com o software desenvolvido no NKI (Holanda) – Wimp. Os testes foram divididos em três estudos diferentes, cada um com um conjunto de dados diferente. No primeiro estudo (estudo A), foram utilizadas 4DCT de 2 fantomas digitais, cuja função respiratória e cardíaca foi modelada de forma simplificada, e de 18 doentes com tumores localizados no pulmão (N = 8), no fígado (N = 6) e no pâncreas (N = 4). Neste estudo, foram comparados dois algoritmos DIR disponíveis no software 3D Slicer, o Plastimatch e o Elastix, em termos da precisão do registo e da qualidade de imagem do Mid-P CT reconstruído. Foi ainda avaliado a capacidade dos softwares RunMidP e Mirada representarem corretamente a posição média do doente e as diferenças das amplitudes do movimento do tumor estimadas pelos dois softwares. No estudo B, foram realizados testes de verificação semelhantes aos supre mencionados, em imagens sintéticas provenientes de 16 doentes, desta vez com a vantagem de se conhecer o “verdadeiro” Mid-P CT e as “verdadeiras” amplitudes do movimento do tumor. Estes foram comparados com os resultados obtidos com os softwares RunMidP e Mirada. Ainda, as unidades de Hounsfield (HU) no Mid-P CT reconstruído por RunMidP e Mirada foram comparadas com as HU na fase de referência, de modo a verificar se os Mid P CTs produziriam diferenças dosimétricas relevantes. No último estudo (estudo C), a qualidade de imagem do Mid-P CT foi avaliada quantitativamente e qualitativamente. Durante a análise qualitativa, foi pedido a dois médicos especialistas que avaliassem a viabilidade dos Mid-P CTs, reconstruídos pelos três softwares (RunMidP, Mirada e Wimp), para o planeamento dos tratamentos. O tempo da reconstrução do Mid-P CT a partir da 4DCT foi de cerca de 1h. Ambos os algoritmos, Plastimach e Elastix, demonstraram ser adequados para DIR de imagens do pulmão e abdómen superior, com diferenças estatisticamente não significativas (p > 0.05) em termos da precisão do registo. Contudo, o Mid-P CT reconstruído com Elastix apresentou uma melhoria na qualidade de imagem, sendo assim o algoritmo DIR escolhido para ser implementado no RunMidP. Em termos de métricas aplicadas a contornos definidos manualmente, tais como a distância de Hausdorf (HD) e coeficiente de Dice (DSC), o erro do registo de imagem foi menor que 1 mm, dentro do contorno do tumor, e 2 mm no pulmão. Os Mid-P CTs reconstruídos com o RunMidP e Mirada apresentaram maiores diferenças, relativamente ao “verdadeiro” Mid-P CT, na região do diafragma e zonas de maior homogeneidade como, por exemplo, no ar presente no intestino. Contudo, para a maioria dos doentes do estudo B, o Mid-P CT reconstruído com o software Mirada apresentou maior índice de similaridade estrutural (SSIM) relativamente ao “verdadeiro” Mid-P CT. Estes resultados podem estar na origem do uso de diferentes algoritmos DIR, mas deveram-se principalmente a uma falha na aplicação das transformações deformáveis pelo módulo RunMiP que foi corrigida posteriormente. Ainda, as diferenças entre as amplitudes estimadas e previstas foram menores que 1 mm para 37 tumores (78,9%), que resultam em diferenças menores que 0.3mm quando convertidas em margens de planeamento. Para além disso, as diferenças nos valores de HU dos Mid-P CTs comparativamente à fase de referência foram, em média, de 1 HU no tumor e OARs. Foram também observadas melhorias na qualidade de imagem do Mid-P CT, nomeadamente um aumento da relação sinal-ruído (SNR) e diminuição dos artefactos. Estes resultados estão de acordo com a avaliação dos médicos que, em geral, consideraram que os Mid-P CTs reconstruídos pelos três softwares são adequados para o planeamento dos tratamentos. No entanto, os Mid-P CTs reconstruídos com dados 4DCT provenientes do CCC apresentaram classificações inferiores aos reconstruídos com dados 4DCT do NKI. Em suma, as modificações do algoritmo DIR Plastimach para Elastix e a correção do método para aplicar as transformações deformáveis, permitiram uma melhoria na qualidade de imagem do Mid P CT e melhor performance do algoritmo, respetivamente. O módulo RunMidP, neste projeto otimizado e validado, apresenta um forte potencial para a reconstrução e implementação da estratégia do Mid-P na clínica, com performance comparável a outras aplicações existentes (Mirada e Wimp). Atenção especial deve ser dada aos dados 4DCT de input que parecem afetar a qualidade de imagem final do Mid-P CT. No futuro, valerá a pena otimizar os parâmetros de aquisição e reconstrução da 4DCT de modo a melhorar a qualidade de imagem e, ainda, o módulo RunMidP pode potencialmente ser otimizado no que respeita ao tempo de reconstrução do Mid-P CT e à precisão do DIR.Radiotherapy for tumours in the thorax and upper abdomen is challenging since they move notably with breathing. To cover the whole extent of tumour motion, relatively large margins are added to treatment volumes, posing a higher risk of toxicity for surrounding organs-at-risk (OARs). The Mid Position (Mid-P) method accounts for breathing motion by using deformable image registration (DIR) to transform all phases of a 4DCT scan to a time-weighted average 3DCT scan (Mid-P CT). The Mid-P strategy results in smaller treatment volumes, potentially boosting the delivery of hypofractionated treatments. To bring the Mid-P approach to the Champalimaud Clinical Centre (CCC), an in-house Mid position software module – RunMidP – was optimized. The module reconstructs the Mid-P CT and estimates breathing motion amplitudes of tumours and relevant OARs. In addition, this project presents a set of experiments to evaluate the performance of the Mid-P method and its feasibility for clinical implementation. The experiments were conducted throughout three different studies using 4DCT data from 18 phantoms and 23 patients. In Study A, the accuracy and image quality of two DIR algorithms (Plastimatch and Elastix) were assessed using quantitative metrics applied on either warped images or manually delineated contours. The reproduction of the patient’s mean position by the Mid-P CT and the estimation of motion amplitudes were compared to a soon-to-be Mid-P commercial software developed by Mirada Medical Ltd. In Study B,similar experiments were performed, this time using a more rigorous reference – “true” Mid-P CT scans and “true” motion estimations. In Study C, the image quality of Mid P CT scans was assessed quantitatively and qualitatively. Both Plastimatch and Elastix registration showed comparable registration accuracy, although Elastix showed superior image quality of reconstructed Mid-P CTs. Based on contour metrics, the registration error was less than 2 mm. In-house Mid-P CTs showed a slightly lower match to ground truth Mid-P CTs than the ones reconstructed by the Mirada prototype due to differences in DIR methods and small shifts to the original image geometry. Higher image differences were found in the diaphragm lung interface, where the patient's anatomy moves faster due to breathing, and in homogeneous regions such as the air regions in the bowel. On the other hand, differences (estimated-predicted) in motion amplitudes smaller than 1 mm were observed in 37 moving tumours (78.7%), showing a good performance of the Mid-P algorithm. Regarding the image quality, improvements in the signal-to-noise ratio and removal of image artefacts in Mid-P CTs are great advantages for using them as the planning CT. Clinicians also gave a good assessment of the suitability of Mid-P CT scans for treatment planning. No significant differences were found in the performance of the RunMidP compared to other Mid-Position packages, although worse scores were given to the CCC dataset than the dataset from another hospital. The in-house Mid-position algorithm shows promising results regarding the use of the software module in radiotherapy for lung and upper abdomen cancer. Further exploration must be given to improve the registration accuracy, image quality of the input data, and speed up the reconstruction of the Mid-P CT scan