"uuid","repository link","title","author","contributor","publication year","abstract","subject topic","language","publication type","publisher","isbn","issn","patent","patent status","bibliographic note","access restriction","embargo date","faculty","department","research group","programme","project","coordinates"
"uuid:20bf6b32-ef07-4bfd-8e44-f340e57b77e4","http://resolver.tudelft.nl/uuid:20bf6b32-ef07-4bfd-8e44-f340e57b77e4","Modelling X-Ray photon transport through a transformer-based neural network in computed tomography forward projection","Hoendermis, Dora (TU Delft Mechanical, Maritime and Materials Engineering; TU Delft RST/Medical Physics & Technology)","Perko, Z. (mentor); Goorden, M.C. (mentor); Vos, F.M. (graduation committee); Delft University of Technology (degree granting institution)","2023","Radiotherapy is one of the main treatments for cancer and relies heavily on CT images to calculate radiation dose. With research on radiotherapy moving to adaptive treatments aiming to calculate these doses at real-time speeds while maintaining high precision, a need for accurate CT imaging at comparable real-time speeds has emerged. Currently, the best performing CT image reconstruction methods are iterative reconstruction (IR) methods, which suffer from slow reconstruction speed. Faster methods are accompanied by artifacts due to the implementation of simplified physics models.
Recently, the Dose Transformer Algorithm (DoTA) [47], [48] and improved DoTA (iDoTA) [49] have shown to successfully calculate radiation therapy dose by modelling particle transport in 3D with the use of a neural network. By implementing a Transformer architecture [62], DoTA is able to capture the relationship between elements in a 3D CT volume while processing it as an input sequence. This results in an accurate prediction of particle transport, while significantly reducing computation times compared to other methods.
A neural network based on the DoTA-architecture is presented. It predicts projection data from CT input, modelling the x-ray photon transport. The network processes 2D CT images as a sequence of 1D lines. The ground truth data contains Monte Carlo projections of cylindrical water phantoms with inserts composed of five different materials.
The predictions are compared to Monte Carlo projections and raytracing projections generated with Astra Toolbox [45], as well as a Two-Angle Convolution (TAC) network [11]. The average NRMSE of the Transformer predictions was 0.725% compared to 2.20% and 1.09% respectively for the raytracer and TAC. The Transformer showed the ability to predict from unseen types of geometries and intensity values. Due to bias in the training data, it does not generalize well to input phantoms with an unseen outer shape.
Two phantoms were reconstructed using the network within an IR algorithm. For the Transformer and raytracer, the highest achieved CNR values are similar for low-contrast regions (6.88 and 8.28 for the raytracer compared to 7.10 and 7.35 for the Transformer) as well as high-contrast regions (37.40 and 41.94 for the raytracer compared to 39.01 and 39.80 for the Transformer). Convergence rates based on low-contrast CNR are higher for the raytracer (39 and 34 iterations compared to 41 and 41 iterations for the Transformer, respectively). The Transformer performs significantly better than the raytracer with respect to beam-hardening artefacts. The IR algorithm has not been tuned for use with the Transformer, suggesting that a higher performance is obtainable with adjustments such as the implementation of a different backprojector or a different value for correction factors used in the algorithm.
Limitations in prediction quality are likely related to factors outside of the model predictions, such as biases in the input data and resolution loss due to interpolation of the input data. When its prediction speed is optimised, the CT Transformer model has potential to replace conventional forward projections in IR methods, achieving Monte Carlo-level accuracy with a fraction of the computation time.
Imaging data from 102 patients with malignant (hepatocellular carcinoma) and benign (focal nodular hyperplasia and hepatocellular adenoma) primary liver tumors was used for binary classification through radiomics and deep learning approaches. The radiomics method was applied with the use of the open-source toolbox WORC. The deep learning model was based on the ResNet-10 architecture. The data input consisted of individual and combined phases of contrast-enhanced T1-weighted and T2-weighted MRI.
The highest performance values were found for the radiomics approach that combined the precontrast, arterial, portal venous, and delayed contrast phases together with T2-weighted MRI, with an AUC of 0.92. The deep learning model scored an AUC of 0.83 with this data input, however substantial overfitting occurred due to the limited sample size.
In conclusion, the radiomics classifiers based on combined contrast-enhanced T1-weighted and T2-weighted MRI can differentiate malignant from benign primary liver tumors with limited data samples. The classification task is too complex with the given data when using a ResNet-10 model and should be applied to an extended dataset.","Radiomics; Deep Learning; ResNet; MRI; Post-contrast T1; Liver cancer; Machine Learning","en","master thesis","","","","","","","","","","","","Biomedical Engineering | Medical Physics","",""
"uuid:cb425bca-3da1-41d9-88a2-7ecdfec21f2f","http://resolver.tudelft.nl/uuid:cb425bca-3da1-41d9-88a2-7ecdfec21f2f","Parametric Relaxation Along a Fictitious Field (pRAFF) Pulse for Robust Quantitative MRI: A Parameterized Exploration of the Subadiabatic and Adiabatic Regimes for Radiofrequency Pulses Design","Naaktgeboren, Roeland (TU Delft Applied Sciences; TU Delft ImPhys/Weingärtner group)","Weingärtner, S.D. (mentor); Coletti, C. (mentor); Vos, F.M. (graduation committee); Esmaeil Zadeh, I.Z. (graduation committee); Delft University of Technology (degree granting institution)","2023","Magnetic resonance imaging (MRI) is a clinical imaging technique that allows for non-invasive visualization inside the human body with excellent soft tissue contrast with a sub-millimeter resolution. Qualitative MRI is used to visually highlight normal or pathological components by exploiting the physical properties of different tissues. However, these acquisitions provide minimal consistency between scans, patients, and scanners. To address this issue, quantitative MRI (qMRI) provides absolute measures that give meaningful physical information about tissues, enabling objective comparisons. Relaxometry, a branch of qMRI that characterizes tissues through their magnetic relaxation properties, has been employed to quantitatively assess various diseases with different biomarkers in the past. However, certain radiofrequency (RF) pulses used to induce relaxation times weighting in the MRI signal are sensitive to field inhomogeneities, which makes consistent quantification of relaxation times difficult. In order to improve sensitivity and detect more diseases, better contrast mechanisms and biomarkers are crucial. One promising technique is Relaxation Along a Fictitious Field (RAFF), which may serve as a biomarker for a wide range of diseases due to its sensitivity to slow molecular motion in tissue. Currently, it has the downside of being sensitive to off-resonance and B1+ artifacts, which hampers clinical application. This project aims to develop novel contrasts for quantitative MRI by investigating the performance of adapted RF pulses. Ultimately, the goal is to reduce the susceptibility to off-resonance and B1+ artifacts for the RF pulses.","MRI; RAFF; Relaxation mapping; Field inhomogeneities","en","master thesis","","","","","","","","","","","","Applied Physics","",""
"uuid:c8b925b2-11ce-4029-b377-c0af6884cedb","http://resolver.tudelft.nl/uuid:c8b925b2-11ce-4029-b377-c0af6884cedb","Low Field Magnetic Resonance Imaging of the Eye: Inexpensive MRI for Ocular Conditions","Haasjes, Corné (TU Delft Mechanical, Maritime and Materials Engineering; Leiden University Medical Center)","Beenakker, J-W.M. (mentor); Remis, R.F. (mentor); Vos, F.M. (graduation committee); Herder, J.L. (graduation committee); Delft University of Technology (degree granting institution)","2022","Ultrasound imaging is an important modality in ocular oncology, allowing for fast examination of the eye by the ophthalmologist themselves. It is clinically used to measure tumour sizes for treatment planning. However, ocular ultrasound is limited to two-dimensional imaging, and suffers from poor contrast between tumour and sclera, which negatively impacts the accuracy of tumour measurements. In this work, low field MRI is investigated as a possible alternative for ultrasound imaging.
Design requirements are a scan time of less than 4 minutes; resolution of 1.0 mm isotropic; Field of View (FOV) large enough to contain the eye and the orbit; contrast sufficient to distinguish the sclera, vitreous, tumour, lens and lipid. The experimental setup consists of a 46 mT Halbach-array based scanner, a volume coil as transmit coil and a custom-built surface coil as receive coil. Images are made of a water phantom to characterise the FOV, and a porcine eye to characterise the contrast.
The FOV is found to meet the requirements, and the contrast is sufficient to distinguish the sclera, vitreous, lens and lipid in porcine eyes. The resolution is too low and the scans take too long (about 5 minutes at a resolution of 1.0 × 1.0 × 7.5 mm). Increasing the resolution and decreasing the scan time will result in a low Contrast to Noise Ratio (CNR), causing the contrast requirement to be violated. Fast, high-resolution three-dimensional imaging is therefore not feasible on the current system.
The CNR can be improved by using a higher field strength, which requires the development of new hardware. Furthermore, in order to develop a clinically useable system, it is necessary to determine tumour contrast, design optimised pulse sequences, and test the method on human subjects.","low field MRI; eye; uveal melanoma; feasibility study","en","master thesis","","","","","","","","","","","","Biomedical Engineering | Medical Physics","",""
"uuid:9456fb86-8441-478c-a1ee-f531eaa25c09","http://resolver.tudelft.nl/uuid:9456fb86-8441-478c-a1ee-f531eaa25c09","Validation of Quantitative MRI: Fat Quantification and ADC Mapping in the Head-and-Neck Area","de Jong, Renske (TU Delft Mechanical, Maritime and Materials Engineering)","Astreinidou, E. (mentor); Vos, F.M. (graduation committee); Staring, M. (graduation committee); Delft University of Technology (degree granting institution)","2021","Fat fraction (FF) and apparent diffusion coefficient (ADC) values estimated by Dixon MRI and diffusion weighted MRI (DWI) techniques respectively, are relatively new quantitative imaging parameters and increasingly accepted as imaging biomakers for all sorts of purposes. The aim of the BOCASEcA study is to research whether these techniques can be used as biomarkers for patient-reported xerostomia and dysphagia post-radiotherapy. In this project, steps have been taken to validate the use of certain fat quantification and ADC mapping protocols in the BOCASEcA study. mDIXON Quant is a Philips product designed for MR fat quantification. We performed phantom studies and a healthy volunteer study to evaluate the accuracy and repeatability of a standard mDIXON Quant protocol with default parameters and an mDIXON Quant protocol that is used in LUMC on muscles throughout the whole body. Another phantom study was done to evaluate the (geometrical) accuracy of DWI-SPLICE, a technique that can be used for ADC mapping. This DWI technique is known to have less susceptibility issues than conventional EPI-DWI. We tested both the accuracy and deforming artifacts for an EPI sequence and a clinically used DWI-SPLICE protocol from LUMC. Adequate accuracy and robustness were observed for the standard Philips mDIXON Quant protocol. The LUMC muscle protocol, however, yielded incorrect measurements that were underestimations of the real FF values. The DWI-SPLICE protocol showed better geometrical accuracy than the EPI protocol. Accuracy of the ADC measurements was sufficient for ADC values higher than 0.6 x 10−3 mm2/s which is a clinically relevant range. Since the accuracy of both the standard Philips mDIXON Quant protocol and DWI-SPLICE protocol was validated, it is recommended that they are used and further optimized for the BOCASEcA study.","Quantitative MRI; Salivary glands; Swallowing muscles; Phantom study; MRI","en","master thesis","","","","","","","","","","","","Biomedical Engineering","",""
"uuid:066db715-3bcf-4e4f-b971-0a06169ba362","http://resolver.tudelft.nl/uuid:066db715-3bcf-4e4f-b971-0a06169ba362","Conceptual probabilistic treatment planning approaches to deal with microscopic disease as an alternative to the Clinical Target Volume","Niekolaas, Sofieke (TU Delft Mechanical, Maritime and Materials Engineering)","Perko, Z. (mentor); Lathouwers, D. (graduation committee); Vos, F.M. (graduation committee); Delft University of Technology (degree granting institution)","2021","Radiotherapy is one of the main treatment modalities available to treat cancer. Radiotherapy treatment plans are created based on CT scans of the patient. In such scans the macroscopic tumor is visible, but microscopic disease present in the surrounding tissue cannot be observed. To achieve an optimal clinical outcome, both the macroscopic and the microscopic disease must be treated. Currently, the macroscopic tumor is extended by a margin into the Clinical Target Volume (CTV) to include the microscopic disease in the treated volume. The same margin is used for all patients, although the extent of microscopic disease is patient-specific and can vary largely among patients.
In this study, probabilistic treatment planning was investigated as a method to replace the margin concept. Probabilistic models were created by explicitly modeling uncertainties in the microscopic disease into an objective function used in the treatment plan optimization. By optimizing either the expected Tumor Control Probability (ETCP) or the expected Logarithmic Tumor Control Probability (ELTCP), optimal dose distributions could be obtained. Two different one-dimensional models for probabilistic treatment planning were investigated.
In the first model, the uncertainty in the extent of the microscopic disease was modeled into an objective function. This was done using a function that describes the probability of finding microscopic disease at a certain distance from the macroscopic disease. In the second model, the uncertainty in the tumor cell density in the microscopic disease area was modeled into an objective function. The uncertainty was modeled by defining the tumor cell density field as a random field and generating different realizations of the tumor cell density field using a Karhunen-Loève (KL) expansion.
For the first model, both the ETCP and the ELTCP were used as objective functions and in the second model, only the ETCP was used as an objective function. Furthermore, a penalized ETCP objective function was investigated for both models. In this penalized objective function a penalty on the dose was used to allow for controlling the balance between tumor control and sparing of normal tissue.
Using the first model, two different types of dose distributions were found. When the ETCP was optimized, the maximum dose was given to as large a volume as possible and no dose was given in the rest of the investigated volume. When the ELTCP was optimized, dose was given throughout the volume, so that the whole volume received as much dose as possible. Optimization of both objectives resulted in good tumor control. When the penalized ETCP was optimized, dose was given to a much smaller part of the volume than with the unpenalized objective, while the tumor control was still good.
Using the second model, it was shown that the KL-expansion is a promising method to model the uncertainty in tumor cell density. Different shapes of the input mean tumor cell density field were investigated. Optimizing the ETCP resulted in realistic dose distributions. Good tumor control was obtained for the different shapes of the input mean tumor cell density field. Furthermore, using the penalized ETCP, good tumor control was retained, while the dose deposited in the volume was decreased.
In conclusion, probabilistic treatment planning promises to be a good alternative to the current margin concept. It was shown that good tumor control could be achieved in the microscopic disease area using probabilistic objective functions. Both models showed promising results and the penalized objectives showed that it is possible to balance between tumor control in the microscopic disease area and sparing of normal tissue. Additional research is necessary to extend the one-dimensional KL-model into a more detailed three-dimensional model. Furthermore, the objectives need to be implemented in treatment planning systems to create real patient plans. Such studies should be performed in cooperation with clinicians and radiologists.
Methods: In this thesis, 13 patients with metastatic brain metastases were included and underwent a magnetic resonance imaging (MRI) scan with a vasoactive stimulus at baseline and three months after the same MRI-scan with stimulus. On the same day as the baseline MRI-scan, the patients received RT. CVR maps were calculated using the MRI-scan with the vasoactive stimulus. An additional computed tomography scan was obtained from each patient prior to their first MRI scan. All scanning data was brought into spatial correspondence with a developed image registration pipeline. After the scanning data was registered image analysis was performed using a VOI- and dose-based analysis.
Results: The performance of the image registration pipeline was close to optimal for the MRI scans, and 69% for the baseline CT scan. The image analysis found a significant increase of CVR at an increasing distance from the tumour for white matter (WM) (p = 0.050). For grey matter (GM) and WM, a significant increase of CVR was found at 14 pixels away from the tumour in comparison to 2 pixels away from the tumour (WM: p = 0.039, and GM: p = 0.046). In the dose-based analysis, a nonsignificant decrease of mean CVR was found after RT. The decrease in CVR after RT did also not depend on the received dose.
Conclusions: This thesis developed an image registration pipeline that can be used in further analysis with this specific patient group and scanning data. The image analysis showed an significant increase in CVR at a distance from the tumour for GM and WM. These results indicate that BM influences the CVR of these patients. However, no conclusions can be drawn based on the dose-based analysis. Additional research needs to be done to relate changes in CVR to cognitive decline in patients with metastatic brain tumours.
use on DXA scans and incorporating ethnic information into the algorithm.
For this purpose, a DL network was constructed and pre-trained on a large data set of radiographs. Transfer learning was adopted to a data set containing DXA scans. The performance of four different models was measured in mean absolute difference (MAD) to observe the effect of adding gender and ethnic information as extra inputs. Final performance was measured on a lock box, which was kept aside during the entire training and tuning process. To gain more insight, regions important for the assessment by the automated model were being visualised using a modified version of Class Activation Mapping (CAM). Furthermore, a comparison was made with software created for automated BAA on radiographs.
Whether or not adding gender and ethnic information as extra inputs did not show a clear effect on the performance. The final performance on the lock box was an MAD of 6.8 months. The activation maps showed that the carpal region was the most important for the automated BAA. The comparison with the radiograph software showed it was not applicable on DXA scans and emphasised the need for a DXA-specific method.
This is the first study that developed an automated BAA method for the use on DXA scans rather than radiographs and the first that incorporates ethnic information inside the algorithm. An MAD of 6.8 months on a totally independent test set (lock box) is comparable with the inter-observer variability of manual BAA and performances reported for state-of-the-art automated BAA methods on radiographs. This method can contribute to reducing radiation exposure and time-intensiveness of the current BAA procedure.","Bone age; Skeletal maturation; Transfer learning; Deep Neural Networks; DXA","en","master thesis","","","","","","","","2021-06-24","","","","Biomedical Engineering","",""
"uuid:e0e3cd00-6b1f-44ea-9524-ea73b6af2138","http://resolver.tudelft.nl/uuid:e0e3cd00-6b1f-44ea-9524-ea73b6af2138","An international study on the collection and combination of optimised algorithms or predicting progression in Alzheimer’s Disease","Mulder, Lotte (TU Delft Mechanical, Maritime and Materials Engineering)","Vos, F.M. (graduation committee); Bron, Dr. E. E. (mentor); Delft University of Technology (degree granting institution)","2021","Early detection of Alzheimer's Disease (AD), i.e. before symptom onset, would provide the opportunity for development and testing of interventions at earlier stages, when the disease process may still be altered or interrupted. Computer algorithms combining machine learning with non-invasive imaging and other biomarkers for AD have been developed in an effort to improve early detection methods. However, so far, none of the individual algorithms perform at a level that qualifies for clinical use. In this study, we investigated whether combining several existing AD prediction algorithms improves performance and generalisability.
State-of-the-art AD progression prediction algorithms were collected from the TADPOLE-SHARE project. Algorithms were trained on data from the Alzheimer's Disease Neuroimaging Initiative (ADNI) study and made forecasts of the clinical diagnosis (CN, MCI, or AD). These algorithms were combined using i) simple, unlearned fuser methods and ii) learned fuser methods. In total, seven experiments were conducted, exploring different combination strategies with increasing complexity of fusers. Finally, we implemented and added our own individual algorithm, a residual neural network (ResNet). All individual algorithms and ensembles were evaluated with the multiclass area under the curve (mAUC) and the balanced classification accuracy (BCA) performance metrics. Statistical significance was evaluated with the McNemar test.
Results. TADPOLE-SHARE resulted in the collection of eight algorithms, from which five were reused for combination. Overall, combining algorithms slightly improves performance (i.e. increased BCA and mAUC), although improvements were not statistically significant (McNemar test). Both BCA and mAUC showed a trend of improved performance with increasing fuser complexity i.e. data learned fusers and re-entering original data features. DoubleResNet was the best performing ensemble (BCA = 0.809 [±0.026], mAUC = 0.902 [±0.020]) and performed slightly better than the best scoring fused algorithm EMCEB (BCA = 0.761 [±0.029]; mAUC = 0.866 [±0.020]).
These preliminary results suggest that combining pre-existing AD progression prediction algorithms might provide the increase in performance and generalisability needed to enable clinical translation. To do so, future work should be focused on increasing the interoperability of currently existing and newly developed algorithms.","Alzheimer's Disease (AD); progression; computer algorithm; ensemble learning; Alzheimer's Disease Neuroimaging Initiative (ADNI); residual network (ResNet)","en","master thesis","","","","","","","","","","","","","",""
"uuid:59c83517-5662-492b-94e7-a7f969631a06","http://resolver.tudelft.nl/uuid:59c83517-5662-492b-94e7-a7f969631a06","AR-assisted craniotomy planning for tumor resection","Wooning, Joost (TU Delft Electrical Engineering, Mathematics and Computer Science; TU Delft Computer Graphics and Visualisation; TU Delft Intelligent Systems)","Marroquim, Ricardo (mentor); Vilanova Bartroli, A. (graduation committee); Vos, F.M. (graduation committee); Walsum, Theo van (mentor); Delft University of Technology (degree granting institution)","2021","A craniotomy is a procedure were a neurosurgeon has to open the skull to gain direct access to the brain. When a brain tumor has to be removed from a patient, the craniotomy position is of great importance. This mostly defines the access path from the skull surface to the tumor and thus also what healthy brain tissue will be removed to access to the tumor itself. To minimize the amount of important brain structures that are removed, the craniotomy has to be carefully planned. This is a complex procedure, where a neurosurgeon is required to mentally reconstruct spatial relations of important brain structures to avoid these as much as possible.
We propose a visualization using augmented reality which may assist in the planning of a craniotomy. In this visualization the goal is to show important brain structures aligned with the physical position of the patient. This should allow better perception of the spatial relations of these structures and thus assist the neurosurgeon. Additionally to the visualization of the structures, we created a heat map that is projected on top of the skull. This should give a quick overview of in which areas there are many important structures between the tumor and the skull surface, and should therefore be avoided.
User studies were conducted amongst neurosurgeons and surgeons from other fields to evaluate the proposed visualization. We found that many of the participants indeed thought that the visualization can assist in surgery. For the specific case of craniotomy planning, several improvements have to be made on the heat map before it can be useful. Nevertheless, the visualization of the structures in itself can assist neurosurgeons in the planning of a craniotomy. Although more work has be performed at practical aspects of the visualization to make it ready for clinical experiments.","Visualization; Augmented Reality; Medical; Craniotomy","en","master thesis","","","","","","","","","","","","","",""
"uuid:b2e20d86-e6b0-470d-a532-2bab7e4f7119","http://resolver.tudelft.nl/uuid:b2e20d86-e6b0-470d-a532-2bab7e4f7119","The increased risk of post-treatment contrast-enhancing brain lesion in IMPT of glioma, and the mitigation thereof in treatment planning","van Doorn, Marleen (TU Delft Mechanical, Maritime and Materials Engineering)","Hoogeman, M.S. (mentor); Habraken, S.J.M. (mentor); Lathouwers, D. (graduation committee); Vos, F.M. (graduation committee); van Vulpen, M. (graduation committee); Delft University of Technology (degree granting institution)","2020","Proton radiotherapy has a dosimetric advantage over photon therapy to spare healthy tissue closely positioned to the tumor mainly due to the absent exit dose. In The Netherlands, the Proton therapy centers currently take a relative biological effectiveness (RBE) of 1.1 compared to photons to deliver an iso-effective treatment. However, initial clinical evidence indicates a variable proton RBE in brain patients with the linear energy transfer (LET) as an important physical parameter. The LET significantly increases at the end of the radiation field, and contributes to an increased probability to develop brain lesions. With the introduction of radiation response models, the first goal of this thesis is to evaluate the impact of the RBE/LET effect in intensity-modulated proton therapy (IMPT) plans. Furthermore, the main goal is to reduce the RBE/LET effect in treatment planning.
We incorporated the probability of lesions origin (POLO) model published in literature to determine the RBE model-based normal tissue complication probability (NTCP) for three glioma patients treated with IMPT at HollandPTC, The Netherlands. The dose and LET distributions were computed using a Monte Carlo system. For the investigation of the RBE/LET effect in treatment planning, we modified several beam settings of the clinical IMPT plan, including the beam angle, beam energy, and robustness. Furthermore, we combined treatment modalities to reduce the NTCP.
We compared the results of the clinically used IMPT plan with the results obtained by the modified IMPT plans. The local redistribution of LETd leads to a decrease in NTCP up to the point when the LETd becomes uniform. The robustness did not reveal deviations in terms of the NTCP. By choosing appropriate beam angles that result in a smeared out
LETd distribution, the NTCP does not improve for small deep located tumors, improves relatively modest by 11.6% for elongated tumors, and significantly improves by 37.0% for large, superficially located tumors. The inclusion of partial transmission beams lowers the NTCP by 30-50% relative to the clinical IMPT plan while limiting the relative increase in mean brain dose by 5-16%. When comparing the IMPT plan with the photon plan used for plan comparison, the VMAT plan always results in the lowest NTCP and provides a relative improvement in NTCP by 60-75%. Meanwhile, the mean brain dose significantly increases by 50-80% compared to the clinical IMPT plan. Intermediate NTCP-Dmean(brain minus CTV) values are achieved when combining protons with the photons or by including proton transmission beams.
In general, we can conclude that the inclusion of partial proton transmission beams is more promising than choosing appropriate beam angles to lower the RBE/LETd effect. However, further optimization of transmission beams is required. Moreover, an improvement in NTCP is always at the cost of the mean dose to healthy tissue. On top, our results support further investigation to combine different modalities, like protons and photon fractionation.","Proton Therapy; Radiotherapy; Radiobiology; Relative Biological Effectiveness; Linear Energy Transfer; Cancer; IMPT; Radiation induced brain lesions; Glioma","en","master thesis","","","","","","","","","","","","Biomedical Engineering | Medical Physics","",""
"uuid:afbb39fc-69b5-4009-b28a-647230890ea8","http://resolver.tudelft.nl/uuid:afbb39fc-69b5-4009-b28a-647230890ea8","Towards an understanding of the electron paramagnetic resonance spectra of the ferritin core: A study of human liver ferritin","Čaluković, Vera (TU Delft Mechanical, Maritime and Materials Engineering)","van der Zant, H.S.J. (graduation committee); Vos, F.M. (graduation committee); Labra Muñoz, J. (graduation committee); Bossoni, L. (mentor); Huber, M. I. (mentor); Delft University of Technology (degree granting institution)","2020","A technique that can be used in the study of the magnetic properties of ferritin is electron paramagnetic resonance (EPR), which is sensitive to the magnetic moments of unpaired electrons.
The magnetic properties of human liver ferritin were studied using 9 GHz EPR, with which temperature dependent spectra were acquired in the following range: 5-150 K. A novel approach, typically used in magnetic resonance spectroscopy, was employed to pre-process the baseline-corrected spectra and remove features for which it was unlikely to originate from the ferritin core. This allowed for the isolation and preservation of the general lineshape of the signal belonging to the ferritin core.
The spectra were further analysed using both a phenomenological approach and by employing the Spin Hamiltonian.
The phenomenological analysis showed that in the 20-70 K temperature range, the amplitude peak-to-peak of the ferritin-core signal decreases linearly with decreasing temperature, while its lineshape changes from Lorentzian to Gaussian between 150 and 70 K. The blocking temperature was suggested to occur between 10 and 20 K, where the signal amplitude was lost.
Whether and how the lineshape of the ferritin core signal shifts or broadens below 70 K could not be determined due to a six-line signal contamination, most likely caused by manganese impurities, obscuring the ferritin-core signal in the field range where its resonance field is positioned.
In order to study the magnetic properties of the ferritin core, and therefore gain insight on the magnetic and electronic structure of the ferritin core, a Spin Hamiltonian approach was employed. The simplified Giant Spin Hamiltonian model featured a single spin system with total spin S = 10. This analysis suggests that the ferritin-core signal is centred at g’=2.0154, hinting at a core composition of magnetite or maghemite, rather than of ferrihydrite.
An almost fully automated procedure to pre-process a set of human liver ferritin EPR spectra obtained at different temperatures is described in this thesis.
This work focuses on what is needed to improve diagnosing and tracking of peripheral arterial disease (PAD) using visualisation techniques. Visualising the blood flow pulsation in the skin can be useful in cases of arterial diseases, as the diseases can influence the blood flow by obstructions and arterial stiffness. The main objective in the visualisation is to show the acceleration of the blood flow, as this is linked to the arterial stiffness.
The proposed algorithm for visualising the acceleration of the blood flow is comprised of multiple steps, including techniques such as motion reduction, Eulerian video magnification, remote photoplethysmography signal extraction and using the second derivative. The input of this algorithm are videos of the skin of patients, this makes this method easy and non-invasive.
Photoplethysmography (PPG) signals are present in videos of skin, but can not be seen with the naked eye. Using Eulerian video magnification the PPG signals are amplified for better processing and visibility. By combining groups of pixels into small patches, a decrease in processing time is achieved and it adds a filtering effect. The size of the patches controls the resolution of the visualisation. Movement from the camera or patient is detrimental when extracting the PPG signal from the video. To counteract the motion in the videos a motion reduction step, using optical flow, is applied. Using the Plane-orthogonal-to-skin (POS) algorithm, the signal extracted from videos is converted to a PPG signal. Calculating the second derivative of the PPG signal gives the acceleration of the signal. By splitting the acceleration signal into positive and negative numbers, the acceleration and deceleration of the blood flow is visualised.
Synthetic videos simulating the skin were generated in various levels of accuracy to aid the development of the algorithm and to conduct experiments. The levels range from a simple pulsating square to a moving PPG signal over a blood vessel like structure. In addition, real videos of patients were used.
The experiments show the feasibility of visualising the acceleration of the blood flow pulsation in the skin, but also highlights areas of improvements and future research. More fine-tuning of the algorithm is needed, in addition to acquiring more videos of patients with PAD before and after surgery in a controlled environment.
A working proof of concept of the algorithm is shown. It has the potential of being a novel method of diagnosing and tracking arterial diseases.","acceleration; video; magnification; blood flow; skin; second derivate; peripheral arterial disease; visualisation; pulsation","en","master thesis","","","","","","","","2021-09-24","","","","","",""
"uuid:28f96ac7-f5ae-43af-9ba0-14832af5c103","http://resolver.tudelft.nl/uuid:28f96ac7-f5ae-43af-9ba0-14832af5c103","The applicability of deep learning to detect the progress of laparoscopic surgery using video recordings","Meij, Senna (TU Delft Mechanical, Maritime and Materials Engineering; TU Delft Biomechanical Engineering; Spaarne Gasthuis, Haarlem, The Netherlands)","van den Dobbelsteen, J.J. (mentor); Vos, F.M. (graduation committee); Vijfvinkel, T.S. (graduation committee); Guédon, A.C.P. (graduation committee); Delft University of Technology (degree granting institution)","2019","The operating room is one of the most complex and expensive environments in the hospital. Research has been focusing on improving the efficient use of the OR time, for instance by using intraoperative data to update the planning of the OR during the day. This thesis used a deep learning network to automatically recognize surgical tools and pre-defined surgical phases present in the recordings, to ultimately track the progress of the procedure. The aim of this thesis is to assess the performance and applicability of this deep learning method for the use of image recognition in a medical environment. To ultimately predict the remaining surgery duration and improve the efficiency of the OR planning. Two datasets of laparoscopic recordings were used, one containing laparoscopic cholecystectomies and one containing total laparoscopic hysterectomies. The surgical tools and the pre-defined phases of the procedure were annotated in every recording, after which the deep learning network was trained with this data. The performance of the network was tested in multiple experiments. The results showed that the performance of the deep learning network was promising and in line with published literature, but that the results varied between recordings. An experiment using three different sized datasets showed that a larger dataset corresponded with the best results and results that varied the least between recordings. Testing the generalizability of the network showed that a network trained on one type of surgery can also be used to recognize similar tools in a different type of surgery. Important is that the tools have the same design. It was found that the most important resources for a project like this are a dedicated hardware with image recognition software and time. This thesis showed the applicability of a deep learning network to automatically recognize the progress of a surgery and provided insight into the steps that need to be taken to use it on a larger scale.","Deep learning; Image recognition; surgery progress","en","master thesis","","","","","","","","2020-12-12","","","","Biomedical Engineering","",""